Embodiments of the present invention relate generally to a distance measuring device and a distance measuring method.
In recent years, keyless entry for facilitating unlocking and locking of a car has been adopted in many cars. This technique performs unlocking and locking of a door using communication between a key of an automobile and the automobile. Further, in recent years, a smart entry system that makes it possible to perform, with a smart key, unlocking and locking of a door lock and start an engine without touching a key has been also adopted.
However, a lot of incidents occur in which an attacker intrudes into communication between a key and an automobile and steals the automobile. As measures against the attack (so-called relay attack), a measure for measuring the distance between the key and the automobile and, when determining that the distance is equal to or larger than a predetermined distance, prohibiting control of the automobile by communication is examined.
As a distance measuring technique, many techniques exist, such as a two-frequency CW (continuous wave) scheme, an FM (frequency modulated) CW scheme, a Doppler scheme, and a phase detection scheme. In general, in distance measurement, a distance from a measuring device to a target object is calculated by providing a transmitter and a receiver in the same housing of the measuring device, hitting a radio wave emitted from the transmitter against the target object, and detecting a reflected wave of the radio wave with the receiver.
However, when taking into account a relatively small reflection coefficient of the target object, limitation on output power due to the Radio Law, and the like, in the distance measuring technique for measuring a distance using the reflected wave, a measurable distance is relatively small and the technique is insufficient to be used in the measures against the relay attack.
A distance measuring device according to an embodiment is a distance measuring device that calculates a distance between a first device and a second device, at least one of which is movable, on a basis of phases of first to fourth known signals transmitted at a plurality of carrier frequencies, the first device including a first reference signal source and a first transceiver configured to transmit the first known signal corresponding to a first carrier frequency and the second known signal corresponding to a second carrier frequency different from the first carrier frequency and receive the third known signal corresponding to the first carrier frequency and the fourth known signal corresponding to the second carrier frequency, using an output of the first reference signal source, in which the second device includes a second reference signal source configured to operate independently from the first reference signal source and a second transceiver configured to transmit the third known signal corresponding to the first carrier frequency and the fourth known signal corresponding to the second carrier frequency and receive the first known signal and the second known signal using an output of the second reference signal source, the first or second device includes a first phase detector configured to detect phases of the third and fourth known signals received by the first transceiver, the first or second device includes a second phase detector configured to detect phases of the first and second known signals received by the second transceiver, the first or second device includes a calculating section configured to calculate a distance between the first device and the second device on a basis of a phase difference between the third and fourth known signals detected by the first phase detector and a phase difference between the first and second known signals detected by the second phase detector, and the first transceiver and the second transceiver transmit/receive the first known signal and the third known signal corresponding to the first known signal one time each and transmit/receive the second known signal and the fourth known signal corresponding to the second known signal one time each, performing transmission/reception a total of four times.
Embodiments of the present invention are explained below in detail with reference to the drawings.
In the present embodiment, an example is explained in which a phase detection scheme for detecting a phase of an unmodulated carrier is adopted and communication-type distance measurement for calculating a distance between respective devices through communication between the respective devices is adopted. In a general phase detection scheme for detecting a phase of a reflected wave, a measurable distance is relatively short as explained above. Therefore, in the present embodiment, the communication-type distance measurement for performing communication between devices is adopted. However, since respective transmitters of the respective devices independently operate from each other, initial phases of transmitted radio waves from the respective transmitters are different from each other. An accurate distance cannot be calculated by the phase detection scheme in the past for calculating a distance according to a phase difference. Therefore, in the present embodiment, as explained below, phase information calculated by reception of one device is transmitted to the other device to make it possible to calculate an accurate distance in the other device.
In adopting such a distance measuring technique, the present embodiment is intended to allow a communication time period required for distance measurement to be shortened as in the case of a four-times repeated alternating sequence which is described later. A basic configuration of a communication type distance measuring technique adopted in the present embodiment is explained below with reference to
<Basic Configuration of Communication Type Distance Measuring Technique>
First, in order to explain distance measurement according to a phase detection scheme adopted in the present embodiment, the principle of distance measurement by the phase detection scheme for detecting a phase using a reflected wave and problems of the distance measurement are explained with reference to the explanatory diagrams of
(Phase Detection Scheme)
In the phase detection scheme, for distance measurement, signals having two frequencies deviating from a center angular frequency ωC1 by an angular frequency ±ωB1 are transmitted. In a distance measuring device that measures a distance using a reflected wave, a transmitter and a receiver are provided in the same housing. A transmission signal (a radio wave) emitted from the transmitter is reflected on a target object and a reflected wave of the radio wave is received by the receiver.
As shown in
tx1(t)=cos{(ωC1+ωB1)t+θ1H} (1)
The transmission signal reaches a target object (a wall W) apart from the transmitter by a distance R [m] with a delay time τ1 and is reflected and received by the receiver. Since the speed of the radio wave is equal to the speed of light c(=3×108 m/s), τ1=(R/c) [seconds]. The signal received by the receiver delays by 2τ1 with respect to the emitted signal. Therefore, a received signal (a received wave) rx1(t) of the receiver is represented by the following Equations (2) and (3):
rx1(t)=cos{(ωC1+ωB1)t+θ1H−θ2×Hτ1} (2)
θ2×Hτ1=(ωC1+ωB1)2τ1 (3)
That is, the transmission signal is received by the receiver with a phase shift of a multiplication result (θ2×Hτ1) of the delay time and the transmission angular frequency.
Similarly, as shown in
tx1(t)=cos{(ωC1−ωB1)t+θ1L} (4)
rx1(t)=cos{(ωC1−ωB1)t+θ1L−θ2×Lτ1} (5)
θ2×Lτ1=(ωC1−ωB1)2τ1 (6)
When a phase shift amount that occurs until the transmission signal having the angular frequency ωC1+ωB1 is received is represented as θH1(t) and a phase shift amount that occurs until the transmission signal having the angular frequency ωC1−ωB1 is received is represented as θL1(t), a difference between phase shifts of the two received waves is represented by the following Equation (7) obtained by subtracting Equation (6) from Equation (3):
θH1(t)−θL1(t)=(θ2×Hτ1−θ2×Lτ1)=2ωB1×2τ1 (7),
where, τ1=R/c. Since the differential frequency ωB1 is known, if the difference between the phase shift amounts of the two received waves is measured, the distance R can be calculated as follows from a measurement result:
R=c×(θ2×Hτ1−θ2×Lτ1)/(4ωB1)
Incidentally, in the above explanation, the distance R is calculated taking into account only the phase information. Amplitude is examined below concerning a case in which a transmission wave having the angular frequency ωC1+ωB1 is used. The transmission wave indicated by Equation (1) described above delays by a delay amount τ1=R/c at a point in time when the transmission wave reaches a target object away from the transmitter by the distance R. Amplitude is attenuated by attenuation L1 corresponding to the distance R. The transmission wave changes to a wave rx2(t) represented by the following Equation (8):
rx2(t)=L1×cos{(ωC1+ωB1)t+θ1H−(ωC1+ωB1)τ1} (8)
Further, the transmission wave is attenuated by attenuation LRFL when the transmission wave is reflected from the target object. A reflected wave tx2(t) in the target object is represented by the following Equation (9):
tx2(t)=LRFL×L1×cos{(ωC1+ωB1)t+θ1H−(ωC1+ωB1)τ1} (9)
The received signal rx1(t) received by the receiver is delayed by a delay amount τ1=R/c [seconds] from the target object. Amplitude is attenuated by attenuation L1 corresponding to the distance R. Therefore, the received signal is represented by the following Equation (10):
rx1(t)=L1×LRFL×L1×cos{(ωC1+ωB1)t+θ1H−2(ωC1+ωB1)τ1} (10)
In this way, the transmission signal from the transmitter is attenuated by L1×LRFL×L1 until the transmission signal reaches the receiver. Signal amplitude that can be emitted from the transmitter in distance measurement needs to conform to the Radio Law according to an applied frequency. For example, a specific frequency in a 920 MHz band involves limitation to suppress transmission signal power to 1 mW or less. From the viewpoint of a signal-to-noise ratio of the received signal, it is necessary to suppress attenuation between transmission and reception in order to accurately measure a distance. However, as explained above, since attenuation is relatively large in the distance measurement for measuring a distance using a reflected wave, a distance that can be accurately measured is short.
Therefore, as explained above, in the present embodiment, by transmitting and receiving signals between the two devices without using a reflected wave, attenuation is reduced by LRFL×L1 to increase the distance that can be accurately measured.
However, the two devices are apart from each other by the distance R and cannot share the same reference signal. In general, it is difficult to synchronize the transmission signal with a local oscillation signal used for reception. That is, between the two devices, deviation occurs in a signal frequency and an initial phase is unknown. Problems in distance measurement performed using such an asynchronous transmission wave are explained.
(Problems in the Case of Asynchronization)
In the distance measuring system in the present embodiment, in distance measurement between two objects, two devices (a first device and a second device) that emit carrier signals (transmission signals) asynchronously from each other are disposed in the positions of the respective objects and the distance R between the two devices is calculated. In the present embodiment, carrier signals having two frequencies deviating from a center angular frequency ωC1 by the angular frequency ±ωB1 are transmitted in the first device. Carrier signals having two frequencies deviating from the center angular frequency ωC2 by an angular frequency ±ωB2 are transmitted in the second device.
The distance between the transceivers is represented as 2R to correspond to the distance in the case in which the reflected wave is used. Initial phases of a transmission signal having the angular frequency ωC1+ωB1 and a transmission signal having the angular frequency ωC1−ωB1 transmitted from the device A1 are respectively represented as θ1H and θ1L. Initial phases of two signals having the angular frequencies ωC2+ωB2 and ωC2−ωB2 of the device A2 are respectively represented as θ2H and θ2L.
First, a phase is considered concerning the transmission signal having the angular frequency ωC1+ωB1. The transmission signal represented by Equation (1) described above is output from the device A1. The received signal rx2(t) in the device A2 is represented by the following Equation (11):
rx2(t)=cos{(ωC1+ωB1)t+θ1H−θ2×Hτ1} (11)
The device A2 multiplies together two signals cos{(ωC2+ωB2)t+θ2H} and sin{(ωC2+ωB2)t+θ2H} and a received wave of Equation (11) to thereby separates the received wave into an in-phase component (an I signal) and a quadrature component (a Q signal). A phase of the received wave (hereinafter referred to as detected phase or simply referred to as phase) can be easily calculated from the I and Q signals. That is, a detected phase θH1(t) is represented by the following Equation (12). Note that, in the following Equation (12), since a term of harmonics near an angular frequency ωC1+ωc2 is removed during demodulation, the term is omitted.
θH1(t)=tan−1(Q(t)/I(t))=−{(ωC1−ωC2)t+(ωB1−ωB2)t+θ1H−θ2×Hτ1} (12)
Similarly, when the transmission signal having the angular frequency ωC1−ωB1 is transmitted from the device A1, a detected phase θL1(t) calculated from the I and Q signals obtained in the device A2 is represented by the following Equation (13). Note that, in the following Equation (13), since a term of harmonics near the angular frequency ωC1+ωC2 is removed during demodulation, the term is omitted.
θL1(t)=tan−1(Q(t)/I(t))=−{(ωC1−ωC2)t−(ωB1−ωB2)t+θ1L−θ2L−θ2×Lτ1} (13)
A phase difference between these two detected phases (hereinafter referred to as detected phase difference or simply referred to as phase difference) θH1(t)−θL1(t) is represented by the following Equation (14):
θH1(t)−θL1(t)=−2(ωB1−ωB2)t+(θ1H−θ1L)−(θ2H−θ2L)+(θ2×Hτ1−θ2×Lτ1) (14)
In the distance measuring device in the past that measures a distance using a reflected wave, the device A1 and the device A2 are the same device and share the local oscillator. Therefore, the following Equations (15) to (17) are satisfied:
ωB1=ωB2 (15)
θ1H=θ2H (16)
θ1L=θ2L (17)
When Equations (15) to (17) hold, Equation (14) is equal to Equation (7) described above. The distance R between the device A1 and the device A2 can be calculated according to a phase difference calculated by I and Q demodulation processing for the received signal in the device A2.
However, since the device A1 and the device A2 are provided to be separated from each other and the local oscillators operate independently from each other, Equations (15) to (17) described above are not satisfied. In this case, unknown information such as a difference between initial phases is included in Equation (14). A distance cannot be correctly calculated.
(Basic Distance Measuring Method of the Embodiment)
The signals having the two angular frequencies explained above transmitted by the first device are received in the second device and phases of the respective signals are calculated. The signals having the two angular frequencies explained above transmitted by the second device are received in the first device and phases of the respective signals are calculated. Further, phase information is transmitted from either one of the first device and the second device to the other. In the present embodiment, as explained below, the distance R between the first device and the second device is calculated by adding up a phase difference between the two signals calculated by the reception of the first device and a phase difference between the two signals calculated by the reception of the second device. Note that the phase information may be the I and Q signals or may be information concerning phases calculated from the I and Q signals or may be information concerning a difference between phases calculated from two signals having different frequencies.
(Configuration)
In
An oscillator 13 is controlled by the control section 11 and generates oscillation signals (local signals) having two frequencies on a basis of a reference oscillator incorporated in the oscillator 13. The respective oscillation signals from the oscillator 13 are supplied to a transmitting section 14 and a receiving section 15. Angular frequencies of the oscillation signals generated by the oscillator 13 are set to angular frequencies necessary for generating two waves of ωC1+ωB1 and ωC1−ωB1 as angular frequencies of transmission waves of the transmitting section 14. Note that when the oscillator 13 is constructed of a plurality of oscillators, each of the oscillators is oscillated in synchronization with an output of a common reference oscillator.
The transmitting section 14 can be configured of, for example, a quadrature modulator. The transmitting section 14 is controlled by the control section 11 to be capable of outputting two transmission waves of a transmission signal having the angular frequency ωC1+ωB1 and a transmission signal having the angular frequency ωC1−ωB1. The transmission waves from the transmitting section 14 are supplied to an antenna circuit 17.
The antenna circuit 17 includes one or more antennas and can transmit the transmission waves transmitted from the transmitting section 14. The antenna circuit 17 receives transmission waves from the device 2 explained below and supplies received signals to the receiving section 15.
The receiving section 15 can be configured of, for example, a quadrature demodulator. The receiving section 15 is controlled by the control section 11 to be capable of receiving and demodulating a transmission wave from the device 2 using, for example, signals having angular frequencies ωC1 and ωB1 from the oscillator 13 and separating and outputting an in-phase component (an I signal) and a quadrature component (a Q signal) of the received wave.
A configuration of the device 2 is the same as the configuration of the device 1. That is, a control section 21 is provided in the second device. The control section 21 controls respective sections of the device 2. The control section 21 is configured of a processor including a CPU. The control section 21 may operate according to a computer program stored in a memory 22 and control the respective sections.
An oscillator 23 is controlled by the control section 21 to generate oscillation signals having two frequencies on a basis of a reference oscillator incorporated in the oscillator 23. The respective oscillation signals from the oscillator 23 are supplied to a transmitting section 24 and a receiving section 25. Angular frequencies of the oscillation signals generated by the oscillator 23 are set to angular frequencies necessary for generating two waves of ωC2+ωB2 and ωC2−ωB2 as angular frequencies of transmission waves of the transmitting section 24.
Note that when the oscillator 23 is constructed of a plurality of oscillators, each of the oscillators is oscillated in synchronization with an output of a common reference oscillator.
The transmitting section 24 can be configured of, for example, a quadrature modulator. The transmitting section 24 is controlled by the control section 21 to be capable of outputting two transmission waves of a transmission signal having an angular frequency ωC2+ωB2 and a transmission signal having an angular frequency (ωC2−ωB2. The transmission waves from the transmitting section 24 are supplied to an antenna circuit 27.
The antenna circuit 27 includes one or more antennas and can transmit the transmission waves transmitted from the transmitting section 24. The antenna circuit 27 receives transmission waves from the device 1 and supplies received signals to the receiving section 25.
The receiving section 25 can be configured of, for example, a quadrature demodulator. The receiving section 25 is controlled by the control section 21 to be capable of receiving and demodulating a transmission wave from the device 1 using, for example, signals having angular frequencies ωC2 and ωB2 from the oscillator 23 and separating and outputting an in-phase component (an I signal) and a quadrature component (a Q signal) of the received wave.
Note that a configuration of the image suppression scheme is publicly known. As characteristics of the image suppression scheme, when a higher angular frequency band is demodulated centering on a local angular frequency for a high frequency, that is, ωC1 or ωC2, a signal in a lower angular frequency band is attenuated and, when a lower angular frequency band is demodulated, a signal in a higher angular frequency band is attenuated. This filtering effect is due to signal processing. The same applies to transmission. When the higher angular frequency band is demodulated centering on ωC1 or ωC2, sin(ωB1t+θB1) or sin(ωB2t+θB2> shown in
Note that, in a receiver of the image suppression scheme, a term of harmonics near the angular frequency ωC1+ωC2 is removed during demodulation. Therefore, in an operation explained below, this term is omitted.
The transmitting section 14 is configured of multipliers TM01 to TM04, TM11 and TM12 and an adder TS01, TS02 and TS11. An input signal ITX1 is supplied to the multipliers TM01 and TM03, and an input signal QTX1 is supplied to the multipliers TM02 and TM04. The multipliers TM01 and TM04 receive cos(ωB1 t+θB1) from the oscillator 13 and the multipliers TM02 and TM03 receive any one of ±sin(ωB1 t+θB1) from the oscillator 13.
The multipliers TM01 to TM04, TM11 and TM12 multiply two inputs respectively, the adder TS01 adds up the multiplication results of the multipliers TM01 and TM02 and outputs the addition result to the multiplier TM11, and the adder TS02 subtracts the multiplication result of the TM04 from the multiplication result of the multiplier TM03 and outputs the subtraction result to the multiplier TM12.
The multiplier TM11 receives cos(ωC1+θC1) from the oscillator 13 and the multiplier TM12 receives sin(ωC1+θC1) from the oscillator 13.
The multipliers TM11 and TM12 respectively multiply together the two inputs and give multiplication results to the adder TS11. The adder TS11 adds up outputs of the multipliers TM11 and TM12 and outputs an addition result as a transmission wave tx1.
The receiving section 15 is configured of multipliers RM11 to RM16 and adders RS11 and RS12. A transmission wave of the device 2 is input to the multipliers RM11 and RM12 via the antenna circuit 17 as a received signal rx1. Oscillation signals having the angular frequency ωC1 and phases 90 degrees different from each other are respectively given to the multipliers RM11 and RM12 from the oscillator 13. The multiplier RM11 multiplies together the two inputs and gives a multiplication result to the multipliers RM13 and RM14. The multiplier RM12 multiplies together the two inputs and gives a multiplication result to the multipliers RM15 and RM16.
An oscillation signal having the angular frequency (a local angular frequency for baseband processing) ωB1 is given to the multipliers RM13 and RM15 from the oscillator 13. The multiplier RM13 multiplies together the two inputs and gives a multiplication result to the adder RS11. The multiplier RM14 multiplies together the two inputs and gives a multiplication result to the adder RS12.
An oscillation signal having the angular frequency ωB1 or an inverted signal of the oscillation signal, that is, a signal orthogonal to the oscillation signal having the angular frequency ωB1 given to the multiplier RM13 is given to the multipliers RM14 and RM16 from the oscillator 13. The multiplier RM14 multiplies together the two inputs and gives a multiplication result to the adder RS12. The multiplier RM16 multiplies together the two inputs and gives a multiplication result to the adder RS11.
The adder RS11 subtracts outputs of the multipliers RM13 and RM16 and outputs an addition result as an I signal. The adder RS12 adds up outputs of the multipliers RM14 and RM15 and outputs an addition result as a Q signal. The I and Q signals from the receiving section 15 are supplied to the control section 11.
The circuits shown in
In the present embodiment, the control section 11 of the device 1 controls the transmitting section 14 to transmit two transmission waves having angular frequencies ωC1+ωB1 and ωC1−ωB1 via the antenna circuit 17.
On the other hand, the control section 21 of the device 2 controls the transmitting section 24 to transmit two transmission waves having angular frequencies ωC2+ωB2 and ωC2−ωB2 via the antenna circuit 27.
The control section 11 of the device 1 controls the receiving section 15 to receive the two transmission waves from the device 2 and acquires the I and Q signals. The control section 11 calculates a difference between two phases calculated from the I and Q signals respectively obtained by two received signals.
Similarly, the control section 21 of the device 2 controls the receiving section 25 to receive the two transmission waves from the device 1 and acquires the I and Q signals. The control section 21 calculates a difference between two phases calculated from the I and Q signals respectively obtained by two received signals.
In the present embodiment, the control section 11 of the device 1 gives phase information based on the acquired I and Q signals to the transmitting section 14 and causes the transmitting section 14 to transmit the phase information. Note that, as explained above, as the phase information, for example, a predetermined initial value may be given. The phase information may be I and Q signals calculated from the two received signals, may be information concerning phases calculated from the I and Q signals, or may be information concerning a difference between the phases.
For example, the control section 11 may generate I and Q signals based on phase information of a received signal having an angular frequency ωB2 and supplies the I and Q signals respectively to the multipliers TM11 and TM12 to transmit the phase information.
During the output of the oscillation signal having the angular frequency ωB1, the control section 11 may generate I and Q signals obtained by adding phase information of the received signal having the angular frequency ωB2 to an initial phase of the oscillation signal having angular frequency ωB1 and supply the I and Q signals respectively to the multipliers TM11 and TM12 to transmit the phase information.
The receiving section 25 of the device 2 receives the phase information transmitted by the transmitting section 14 via the antenna circuit 27. The receiving section 25 demodulates a received signal and obtains I and Q signals of the phase information. The I and Q signals are supplied to the control section 21. The control section 21 obtains, according to the phase information from the receiving section 25, a value including the phase difference acquired by the control section 11 of the device 1. The control section 21 functioning as a calculating section adds up the phase difference obtained by the reception result of the receiving section 25 and the phase difference based on the phase information transmitted from the device 2 to calculate the distance R between the first device 1 and the second device 2.
Note that, in
(Basic Operation of Communication Type Distance Measurement)
An operation in such communication type distance measurement is explained using a case where the device 2 calculates a distance as an example and with reference to a flowchart of
In step S1, the control section 11 of the device 1 determines whether an instruction for a distance measurement start is received. When the instruction for the distance measurement start is received, the control section 11 controls the oscillator 13 to start an output of a necessary oscillation signal. In step S11, the control section 21 of the device 2 determines whether an instruction for a distance measurement start is received. When the instruction for the distance measurement start is received, the control section 21 controls the oscillator 23 to start an output of a necessary oscillation signal.
Note that, as explained below, in step S9, the control section 11 ends oscillation. In step S20, the control section 21 ends oscillation. Control of a start and an end of oscillation in the control sections 11 and 21 indicates that oscillation of the oscillators 13 and 23 is not stopped during transmission and reception periods for distance measurement. Actual start and end timings of the oscillation are not limited to the flow shown in
The control section 11 of the device 1 generates two transmission signals in step S3 and causes the antenna circuit 17 to transmit the transmission signals as transmission waves (step S4). The control section 21 of the device 2 generates two transmission signals in step S13 and causes the antenna circuit 27 to transmit the transmission signals as transmission waves (step S14).
It is assumed that an initial phase of an oscillation signal having the frequency ωC1 output from the oscillator 13 of the device 1 is θc1 and an initial phase of an oscillation signal having the frequency ωB1 is θB1. Note that, as explained above, the initial phases θc1 and θB1 are not set anew as long as the oscillation of the oscillator 13 continues.
Note that it is assumed that an initial phase of an oscillation signal having the frequency ωC2 output from the oscillator 23 of the device 2 is θc2 and an initial phase of an oscillation signal having the frequency ωB2 is θB2. The initial phases θc2 and θB2 are not set anew as long as the oscillation of the oscillator 23 continues.
Note that, when simultaneous transmission and simultaneous reception of two frequencies are assumed, two wireless sections shown in
(Transmission and Reception of a Transmission Wave Having the Angular Frequency ωC1+ωB1 from the device 1)
Now in
When the distance between the devices 1 and 2 is represented as R and a delay until a transmission wave from the device 1 is received by the device 2 is represented as τ1, the received signal rx2(t) of the device 2 can be represented by the following Equations (19) and (20):
The received signal rx2(t) is received by the antenna circuit 27 and supplied to the receiving section 25. In the receiver shown in
I1(t)=cos(ωC2t+θC2)×cos{(ωC1+ωB1)t+θc1+θB1−θτH1} (21)
Q1(t)=sin(ωC2t+θC2)×cos{(ωC1+ωB1)t+θc1+θB1−θτH1} (22)
I2(t)=I1(t)×cos(ωB2t+θB2) (23)
Q2(t)=Q1(t)×sin(ωB2t+θB2) (24)
I3(t)=I1(t)×sin(ωB2t+θB2) (25)
Q3(t)=Q1(t)×cos(ωB2t+θB2) (26)
An output I(t) of the adder RS21 is I(t)=I2(t)+Q2(t). An output Q(t) of the adder RS22 is Q(t)=I3(t)−Q3(t). A phase θH1(t) obtained from I(t) and Q(t) is represented by the following Equation (27):
θH1(t)=tan−1(Q(t)/I(t))=−{(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2−θτH1} (27)
(Transmission and Reception of a Transmission Wave Having the Angular Frequency ωC2+ωB2 from the Device 2)
Similarly, ITX2=1 and QTX2=0 are assumed in
The received signal rx1(t) is received by the antenna circuit 17 and supplied to the receiving section 15. In the receiver shown in
I1(t)=cos(ωC1t+θC1)×cos{(ωC2+ωB2)t+θc2+θB2−θτH2} (31)
Q1(t)=sin(ωC1t+θC1)×cos{(ωC2+ωB2)t+θc2+θB2−θτH2} (32)
I2(t)=I1(t)×cos(ωB1t+θB1) (33)
Q2(t)=Q1(t)×sin(ωB1t+θB1) (34)
I3(t)=I1(t)×sin(ωB1t+θB1) (35)
Q3(t)=Q1(t)×cos(ωB1t+θB1) (36)
An output I(t) of the adder RS11 is I(t)=I2(t)+Q2(t). An output Q(t) of the adder RS12 is Q(t)=I3(t)−Q3(t). A phase θH2(t)=tan−1 (Q(t)/I(t)) obtained from I(t) and Q(t) is represented by the following Equation (37):
θH2(t)=(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2+θτH2 (37)
(Transmission and Reception of a Transmission Wave Having the Angular Frequency ωc1−ωb1 from the Device 1)
The signal tx1(t) having the angular frequency ωC1−ωB1 transmitted from the device 1 is calculated in the same manner.
Since the distance between the devices 1 and 2 is R and the delay time is τ1, the received signal rx2(t) in the device 2 is represented by the following Equations (39) and (40):
Signals of the respective nodes of the device 2 can be represented by the following Equations (43) to (47):
I1(t)=cos(ωC2t+θC2)×cos{(ωC1−ωB1)t+θc1−θB1−θτL1} (41)
Q1(t)=sin(ωC2t+θC2)×cos{(ωC1−ωB1)t+θc1−θB1−θτL1} (42)
I2(t)=I1(t)×cos(ωB2t+θB2) (43)
Q2(t)=Q1(t)×{−sin(ωB2t+θB2)} (44)
I3(t)=I1(t)×{−sin(ωB2t+θB2)} (45)
Q3(t)=Q1(t)×cos(ωB2t+θB2) (46)
A phase θL1(t)=tan−1(Q(t)/I(t)) detected by the device 2 from I(t)=I2(t)−Q2(t) obtained from the adder RS21 and Q(t)=I3(t)+Q3(t) obtained from the adder RS22 is represented by the following Equation (47):
θL1(t)=tan−1(Q(t)/I(t))=−{(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)−θτL1} (47)
(Transmission and Reception of a Transmission Wave Having the Angular Frequency ωC2−ωB2 from the Device 2)
Similarly, when the signal tx2(t) having the angular frequency ωC2−ωB2 transmitted from the device 2 is received by the device 1 after a delay τ2, a phase θL2(t) obtained from I(t) and Q(t) detected by the device 1 is calculated.
Signals of the respective nodes of the device 1 can be represented by the following Equations (53) to (57):
I1(t)=cos(ωC1t+θC1)×cos{(ωC2−ωB2)t+θc2−θB2−θτL2} (51)
Q1(t)=sin(ωC1t+θC1)×cos{(ωC2−ωB2)t+θc2−θB2−θτL2} (52)
I2(t)=I1(t)×cos(ωB1t+θB1) (53)
Q2(t)=Q1(t)×{−sin(ωB1t+θB1)} (54)
I3(t)=I1(t)×{−sin(ωB1t+θB1)} (55)
Q3(t)=Q1(t)×cos(ωB1t+θB1) (56)
A phase θL2(t)=tan−1 {Q(t)/I(t)} detected by the device 1 from I(t)=I2(t)−Q2(t) obtained from the adder RS11 and Q(t)=I3(t)+Q3(t) obtained from the adder RS12 is represented by the following Equation (57):
θL2(t)=(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)+θτL2 (57)
In step S6 in
The control section 11 gives acquired phase information to the transmitting section 14 and causes the transmitting section 14 to transmit the phase information (step S8). For example, the control section 11 supplies the I and Q signals based on the phase information instead of the oscillation signals supplied to the multipliers TM11 and TM12 shown in
In step S18, the control section 21 of the device 2 receives the phase information from the device 1. As explained above, the phase information may be the I and Q signals from the receiving section 15 of the device 1, may be information concerning phases obtained from the I and Q signals, or may be information concerning a difference between the phases.
In step S19, the control section 21 performs an operation of the following Equation (58) to calculate a distance. The following Equation (58) is an equation for adding up a difference between Equation (27) and Equation (47) and a difference between Equation (37) and Equation (57).
{θH1(t)−θL1(t)}+{θH2(t)−θL2(t)}=(θτH1−θτL1)+(θτH2−θτL2) (58)
The following Equations (59) and (60) hold:
The delays τ1 and τ2 of radio waves between the devices 1 and 2 are the same irrespective of a traveling direction. Therefore, the following Equation (61) is obtained from Equations (58) to (60):
Since τ1=(R/c), Equation (61) described above indicates that a value proportional to a double of the distance R is calculated by addition of a phase difference between two frequencies by the I and Q signals detected by the device 2 and a phase difference between two frequencies by the I and Q signals detected by the device 1. In general, the angular frequency ωB1 by the oscillator 13 of the device 1 and the angular frequency ωB2 by the oscillator 13 of the device 2 can be matched with an error in the order of several ten ppm. Therefore, the distance R by Equation (61) described above can be calculated at resolution of equal to or higher than at least approximately 1 m.
In step S9, the control section 11 stops the oscillator 13. In step S20, the control section 21 stops the oscillator 23. Note that, as explained above, the control sections 11 and 21 only have to continue the oscillation in a period of transmission and reception in steps S4, S5, S14, and S15. Start and end timings of the oscillation of the oscillators 13 and 23 are not limited to the example shown in
(Calculation of a Distance by a Residue of 2π)
Incidentally, when the addition of the phase differences detected by the device 1 and the device 2 is performed, a result of the addition is sometimes negative values or larger than 2π [rad]. In this case, it is possible to calculate a correct distance R with respect to a detected phase by calculating a residue of 2π.
For example, when R=11 m and ωB1=ωB2=2π×5 MHz, a detected phase difference Δθ12 obtained by the device 1 and a detected phase difference Δθ21 obtained by the device 2 are respectively as represented by the following Equations (62) and (63):
Δθ12=θτH1−θτL1=−1.8849[rad] (62)
Δθ21=θτH2−θτL2=−6.0737[rad] (63)
The following Equation (61a) is obtained from Equation (61) described above:
(½)[{Δθ12}+{Δθ21}]=(θB1+ωB2)(R/c) (61a)
From Equation (61a), −0.3993=(ωB1+ωB2)(R/c) is obtained. When this equation is solved, R=−19 m. It is seen that a distance cannot be correctly calculated because a detected phase difference is larger than −π(rad).
Therefore, in the present embodiment, in such a case, as shown in
2π+(Δθ12+Δθ21)/2=2.3008
From Equation (61a), R is calculated as R=11 m.
Consequently, in the present embodiment, when the detected phase differences are added up, a residue of 2π only has to be calculated to calculate the distance R. Note that the method of using the residue of 2π in the phase addition is applicable in other embodiments.
(Selection from a Plurality of Distance Candidates)
Incidentally, a detected phase difference exceeding 2π cannot be detected. Therefore, a plurality of distance candidates are present with respect to a calculated detected phase difference. As a method of selecting a correct distance from the plurality of distance candidates, a method of transmitting three transmission waves having different angular frequencies and a method of determining a distance according to received power exist.
Since τ1=(R/c), the following Equation (64) is obtained from Equation (61) described above:
(½)×{(θτH1−θτL1)+(θτH2−θτL2)}=(ωB1+ωB2)×(R/c) (64)
When a left side is described as θdet, a relation between the distance R and θdet is as indicated by a solid line in
Referring to
Q>1 (65)
A relation between detected phases at the new angular frequencies and the distance R can be indicated by a broken line shown in
A method of selecting a correct distance according to amplitude observation of a detected signal is explained with reference to the explanatory diagram of
In Equation (8) described above, the amplitude is attenuated at the attenuation L1 according to the distance R. However, propagation attenuation in a free space is generally represented by the following Equation (66):
L1=(λ/4πR)2 (66)
where, λ is a wavelength. According to Equation (66), if the distance R is large, the attenuation L1 is also large and, if the distance R is small, the attenuation L1 is also small.
P1=(λ/4πR1)2×P0 (67)
P2=(λ/4πR2)2×P0 (68)
It is possible to distinguish the distances R1 and R2 from the sum θdet of the detected phase differences and the received power.
Note that, in this case, it is possible to perform sure distance measurement by using the residue of 2π in the phase addition as well.
As explained above, in the basic distance measuring method of the present embodiment, the signals having the two angular frequencies are transmitted from the first device and the second device to the second device respectively and the first device and the two phases of the two received signals having different angular frequencies are respectively calculated in the first and second devices. Any one of the first device and the second device transmits calculated phase information to the other. The device that receives the phase information accurately calculates the distance between the first device and the second device irrespective of initial phases of the oscillators of the first device and the second device according to an addition result of a phase difference between the two received signals received by the first device and a phase difference between the two received signals received by the second device. In the distance measuring system, a reflected wave is not used. The accurate distance measurement is performed by only one-way direction from the first device and the second device. It is possible to increase a measurable distance.
In the above description, Equation (61) described above for calculating a distance from addition of detected phase differences is calculated assuming that the delays τ1 and τ2 of the radio wave are the same in Equation (58) described above. However, Equation (58) is an example in the case in which transmission and reception processing is simultaneously performed in the devices 1 and 2.
However, because of the provision of the Radio Law in the country, a frequency band in which simultaneous transmission and reception cannot be performed is present. For example, a 920 MHz band is an example of the frequency band. When distance measurement is performed in such a frequency band, transmission and reception has to be performed in time series. In the present embodiment, an example adapted to such time-series transmission and reception is explained.
(Problems in the Time-Series Transmission and Reception)
When it is specified that only one wave can be transmitted and received at the same time between the devices 1 and 2, it is necessary to carry out, in time series, transmission and reception of at least four waves necessary for distance measurement. However, when the time-series transmission and reception is carried out, a phase equivalent to a delay that occurs in time series processes is added to a detected phase. A phase required for propagation cannot be calculated. A reason for this is explained by modifying Equation (58) explained above.
Note that a broken line portion of
As described above, in the devices 1 and 2 separated from each other by the distance R, a phase (shift amount) at the time when a signal having the angular frequency ωC1+ωB1 transmitted from the device 1 is detected in the device 2 is represented as θH1, a phase at the time when a signal having the angular frequency ωC1−ωB1 transmitted from the device 1 is detected in the device 2 is represented as θL1, a phase (shift amount) at the time when a signal having the angular frequency ωC2+ωB2 transmitted from the device 2 is detected in the device 1 is represented as θH2, and a phase at the time when a signal having the angular frequency ωC2−ωB2 transmitted from the device 2 is detected in the device 1 is represented as θL2.
For example, phase detection order is set as θH1, θL2, θH2, and θL1. As shown in
{θH1(t)−θL1(t+3T)}+{θH2(t+2T)−θL2(t+T)}=(θτH1−θτL1)+(θτH2−θτL2)+(ωC1−ωC2)4T (79)
A last term of Equation (79) described above is a phase added by the time-series transmission and reception. The added phase is a multiplication result of error angular frequencies of the device 1 and the device 2 with respect to a local angular frequency between the local angular frequencies used in the device 1 and the device 2 and a delay 4T, where the local frequencies are almost the same frequencies as the RF frequencies used in the device 1 and the device 2. When a local frequency is set to 920 [MHz], a frequency error is set to 40 [ppm], and a delay T is set to 0.1 [ms], the added phase is 360°×14.7. It is seen that an error due to the added phase is too large and distance measurement cannot be correctly performed.
The phase detection order is set as θH1, θL1, θH2, and θL2.
{θH1(t)−θL1(t+T)}+{θH2(t+2T)−θL2(t+3T)}=(θτH1−θτL1)+(θτH2−θτL2)+(ωB1−ωB2)4T (80)
A last term of Equation (80) described above is a phase added by the time-series transmission and reception. The added phase is a multiplication result of error angular frequencies between the local angular frequencies for baseband processing used in the device 1 and the device 2 and a delay 4T, where the local frequencies for baseband processing are almost the same frequencies as the baseband frequencies used in the device 1 and the device 2. When a local frequency for baseband processing is set to 5 MHz, a frequency error is set to 40 [ppm], and the delay T is set to 0.1 [ms], the added phase is 360°×0.08=28.8°. It is seen from precedence that distance measurement can be correctly performed.
However, in this case, it depends on a system whether an error is within an allowable error of system specifications. The present embodiment presents a time-series procedure for reducing a distance error that occurs because of the time-series transmission and reception. Note that the present embodiment indicates a procedure that takes into account the regulation of transmission and reception specified by the Radio Law.
(Example of the Specific Procedure (Eight-Times Repeated Alternating Sequence))
First, an influence due to a transmission delay is considered.
The following Equation (81) is obtained by modifying Equation (58) described above:
{θH1(t)+θH2(t)}−{θL1(t)+θL2(t)}=(θτH1+θτH2)−(θτL1+θτL2) (81)
In the equation,
θH1(t)+θH2(t)=θτH1+θτH2 (82)
θL1(t)+θL2(t)=θτL1+θτL2 (83)
In wireless communication, there is a provision that, when a signal addressed to oneself is received, a reply can be transmitted without carrier sense. According to the provision, after transmission of a signal from the device 1 to the device 2 ends, a reply is immediately transmitted from the device 2 to the device 1. To simplify an analysis, it is assumed that the device 2 transmits a reply to the device 1 after to from the transmission by the device 1. The following Equation (84) is obtained from Equations (27) and (37):
θH1(t)+θH2(t+t0)=θτH1+θτH2+{(ωB1−ωB2)+(ωC1−ωC2)}t0 (84)
A delay t0 is a shortest time period and includes a time period in which a signal having the angular frequency ωC1+ωB1 is transmitted from the device 1 to the device 2, a transmission and reception timing margin, and a propagation delay. A third term and a fourth term on a right side are phase errors due to the delay t0. The fourth term is particularly a problem because a frequency is high. This is referred to below.
The delay T is further added to a left side of Equation (84).
θH1(t+T)+θH2(t+t0+T)=θτH1+θτH2+{(ωB1−ωB2)+(ωC1−ωC2)}t0 (85)
A right side of Equation (85) described above and a right side of Equation (84) described above are the same. That is, if a relative time difference is the same (in the example explained above, T), an addition result of a phase in which a signal transmitted from the device 1 is received by the device 2 and a phase in which a signal transmitted from the device 2 is received by the device 1 does not change irrespective of the delay T. That is, the addition result of the phases is a value that does not depend on the delay T.
Transmission and reception of the angular frequency ωC1−ωB1 signal between the device 1 and the device 2 is explained the same. That is, the following Equations (86) and (87) are obtained from Equations (47) and (57) described above:
θL1(t)+θL2(t+t0)=θτL1+θτL2+{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (86)
θL1(t+T)+θL2(t+t0+T)=θτL1+θτL2+{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (87)
From the above examination, a sequence is considered in which, after transmission and reception in both directions of the angular frequency ωC1+ωB1 signal, transmission of reception of the angular frequency ωC1−ωB1 signal is performed. When a transmission start time of the angular frequency ωC1−ωB1 signal from the device 1 is represented as T on a basis of a transmission start time of the angular frequency ωC1+ωB1 signal, the following Equation (88) is obtained from Equations (84) and (87) describe above where, T>t0 is assumed.
θH1(t)+θH2(t+t0)−{θL1(t+T)+θL2(t+t0+T)}=θτH1−θτL1+θτH2−θτL2+2(ωB1−ωB2)t0 (88)
A last term of a left side of Equation (88) described above is a phase error due to a transmission delay. A delay error due to a received local frequency for high-frequency is cancelled by calculating a difference between the angular frequency ωC1+ωB1 signal and the angular frequency ωC1−ωB1 signal. Therefore, the phase error is, in terms of time series, multiplication of a shortest delay time t0 and an error of a local angular frequency (e.g., 2π×5 [MHz]) for a baseband processing. If the delay time t0 is set small, the error is small. Therefore, depending on a value of the delay time t0, practically, it is considered possible to perform distance measurement without a problem in accuracy.
A method of removing the last term of Equation (88) described above, which is a distance estimation error factor, is explained.
The following Equation (89) is obtained from Equations (27) and (37) described above:
θH1(t+t0)+θH2(t)=θτH1+θτH2−{(ωB1−ωB2)+(ωC1−ωC2)}t0 (89)
Even if a predetermined delay D is added to a left side of Equation (89), as explained above, a value of a right side does not change. Therefore, the following Equation (90) is obtained:
θH1(t+t0+D)+θH2(t+D)=θτH1+θτtH2−{(ωB1−ωB2)+((ωC1−ωC2)}t0 (90)
When the Equations (84) and (90) are added up, the following Equation (91) is obtained:
θH1(t)+θH2(t+t0)+θH1(t+t0+D)+θH2(t+D)=2(θτH1+θτH2) (91)
A left side of
θH1(t)+2θH2(t+t0)+θH1(t+2t0)=2(θτH1+θτH2) (92)
A right side of Equation (92) described above is only a term of a radio wave propagation delay corresponding to a distance that does not depend on time.
From Equations (47) and (57) described above, the following Equation (93) is obtained:
θL1(t+t0)+θL2(t)=θτL1+θτL2−{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (93)
Even if the predetermined delay D is added to a left side of Equation (93), a value of a right side does not change. Therefore, the following Equation (94) is obtained:
θL1(t+t0+D)+θL2(t+D)=θτL1+θτL2−{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (94)
When Equations (86) and (94) described above are added up, the following Equation (95) is obtained:
θL1(t)+θL2(t+t0)+θL1(t+t0+D)+θL2(t+D)=2(θτL1+θτL2) (95)
In Equation (95), when D=t0, the following Equation (96) is obtained:
θL1(t)+2θL2(t+t0)+θL1(t+2t0)=2(θτL1+θτL2) (96)
A right side of Equation (96) described above is only a term of a radio wave propagation delay corresponding to a distance that does not depend on time.
Equations (92) and (96) described above mean a sequence for performing phase detection of a transmission signal of the device 1 in the device 2, performing phase detection of a transmission signal of the device 2 in the device 1 after to, and performing the phase detection of the transmission signal of the device 1 in the device 2 again after 2t0. In the following explanation, the process in which transmission of the transmission signal of the device 1 and phase detection in the device 2 for the transmission signal and transmission of the transmission signal of the device 2 and phase detection in the device 1 for the transmission signal alternate and the phase detections are measured again by shifting time is referred to as “repeated alternation”.
That is, the repeated alternation for respectively transmitting and receiving two carrier signals in the devices 1 and 2 and transmitting and receiving the carrier signals again at a to interval from the device 1 or 2 to the other device is performed. Consequently, although the order and time of the transmission are limited, it is possible to perform accurate distance measurement that does not depend on time.
Further, depending on a transmission and reception sequence of carrier signals, even if the repeated alternation is not performed at the t0 interval, it is possible to perform accurate distance measurement that does not depend on time.
That is, even if a fixed delay T is added to a left side of Equation (95) described above, a right side is fixed. Therefore, the following Equation (97) is obtained:
θL1(t+T)+θL2(t+t0+T)+θL1(t+t0+D+T)+θL2(t+D+T)=2(θτL1+θτL2) (97)
The following Equation (98) is obtained from Equations (91) and (97) described above:
θH1(t)+θH2(t+t0)+θH1(t+t0+D)+θH2(t+D)−{θL1(t+T)+θL2(t+t0+T)+θL1(t+t0+D+T)+θL2(t+D+T)}=2{(θτH1−θτL1)+(θτH2−θτL2)}=4×(ωB1+ωB2)τ1 (98)
Equation (98) described above indicates a sequence for, after performing the repeated alternation of reciprocation of the angular frequencies ωC1+ωB1 signal and ωC2+ωB2 signal at the time interval D, performing the repeated alternation of reciprocation of the angular frequencies ωC1−ωB1 signal and ωC2−ωB2 signal at the time interval D after T from a measurement start. By adopting this sequence, it is possible to remove a distance estimation error factor of the last term of Equation (88) described above and perform accurate distance measurement.
Further, the control section 11 transmits a transmission wave having the angular frequency ωC1−ωB1 (hereinafter referred to as transmission wave L1A). Immediately after receiving the transmission wave L1A, the control section 21 of the device 2 transmits a transmission wave having the angular frequency ωC2−ωB2 (hereinafter referred to as transmission wave L2A). Further, after transmitting the transmission wave L2A, the control section 21 of the device 2 transmits a transmission wave having the angular frequency ωC2−ωB2 (hereinafter referred to as transmission wave L2B). After receiving the second transmission wave L2B, the control section 11 of the device 1 transmits a transmission wave having the angular frequency ωC1−ωB1 (hereinafter referred to as transmission wave L1B).
In this way, as shown in
The control section 11 of the device 1 acquires a phase θH2(t+t0) based on the transmission wave H2A in a predetermined time from a time to, acquires a phase θH2(t+D) based on the transmission wave H2B in a predetermined time from a time D, acquires a phase θL2(t+t0+T) based on the transmission wave L2A in a predetermined time from a time t0+T, and acquires a phase θL2(t+D+T) based on the transmission wave L2B in a predetermined time from a time D+T.
At least one of the devices 1 and 2 transmits phase information, that is, calculated four phases or two phase differences or an operation result of Equation (98) described above of the phase differences. The control section of the device 1 or 2, which receives the phase information, calculates a distance according to an operation of Equation (98) described above. Note that, although “calculate a phase difference” is described in steps S7 and S17 in
In this way, in the examples in
Note that in the examples in
<Transmission Sequence for Shortening Communication Time Period>
As described above, the communication type distance measuring technique adopted in the present embodiment adopts the eight-times repeated alternating sequence, and can thereby totally eliminate influences of time shifts and perform accurate distance measurement. However, in the eight-times repeated alternating sequence, the devices 1 and 2 have to transmit two waves, two times each, that is, the device 1 has to transmit waves four times and the device 2 also has to transmit waves four times, thus requiring a relatively long time for distance measurement.
(Four-Times Repeated Alternating Sequence)
Thus, the present embodiment proposes a method (four-times repeated alternating sequence) for measuring a distance in a shorter time while enabling accurate distance measurement.
As shown in
Even in the case where a four-times repeated alternating sequence is adopted, as in the case of the eight-times repeated alternating sequence, a method for carrying out accurate distance measurement by totally eliminating influences of time shifts is explained.
Equations (84) to (87) described above calculated by taking into account a time sequence transmission can be modified into the following Equations (112) to (115) respectively. That is, Equation (112) is obtained by substituting t0 by 2t0 in Equation (84). Moreover, Equation (113) is obtained by substituting T by t0 in Equation (85). Furthermore, as described above, even when a relatively identical delay is added, the addition result of the calculated phases does not change, and therefore Equation (114) is obtained by adding a predetermined delay T to the left side of Equation (86) and substituting t0 by 2t0. Similarly, Equation (115) is obtained by substituting T by T+t0 in Equation (87).
θH1(t)+θH2(t+2t0)=θτH1+θτH2+2{(ωB1−ωB2)+(ωC1−ωC2)}t0 (112)
θH1(t+t0)+θH2(t+2t0)=θτH1+θτH2+{(ωB1−ωB2)+(ωC1−ωC2)}t0 (113)
θL1(t+T)+θL2(t+2t0+T)=θτL1+θτL2+2{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (114)
θL1(t+t0+T)+θL2(t+2t0+T)=θτL1+θτL2+{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (115)
Subsequently, calculating 2×Equation (113)−Equation (112)−{2×Equation (115)−Equation (114)} gives the following Equation (116):
θH2(t+2t0)+2θH1(t+t0)−θH1(t)−{θL2(t+2t0+T)+2θL1(t+t0+T)−θL1(t+T)}=(θτH1−θτL1)+(θτH2−θτL2)=2×(ωB1+ωB2)τ1 (116)
Equation (116) shows that it is possible to calculate a delay time τ1 by adding up the phase differences obtained in the devices 1 and 2. That is, Equation (116) shows that it is possible to accurately measure distance by removing a distance estimation error factor as in the case of Equation (98) that shows the aforementioned eight-times repeated alternating sequence.
Furthermore, Equation (116) shows that phases are measured a total of 6 times. That is, Equation (116) shows that it is possible to sequentially measure detected phase θH1(t) of the device 2 when time t=0, detected phase θH1(t+t0) of the device 2 when time t=t0, detected phase θH2 (t+2t0) of the device 1 when time t=2t0, detected phase θL1(t+T) of the device 2 when time t=T, detected phase θL1(t+t0+T) of the device 2 when time t=t0+T and detected phase θL2(t+2t0+T) of the device 1 when time t=2t0+T.
In this case, phases θH1(t) and θH1(t+t0) can be measured by a single transmission sequence and phases θL1(t+T) and θL1(t+t0+T) can be measured by a single transmission sequence.
Furthermore, the control section 11 of the device 1 transmits a transmission wave having an angular frequency of ωC1−ωB1 at timing corresponding to t=T and t=t0+T. The control section 21 of the device 2 transmits a transmission wave having an angular frequency of ωC2−ωB2 at timing corresponding to t=2t0+T immediately after receiving the transmission wave.
In this way, as shown in
Furthermore, the control section 11 of the device 1 acquires phase θH2(t+2t0) on a basis of the received signal at time t=2t0 and acquires phase θL2(t+2t0+T) on a basis of the received signal at time t=2t0+T.
One of the device 1 and the device 2 that have measured the phase in the four-times repeated alternating sequence transmits phase information acquired at the own device to the other of the device 1 and the device 2. Of the device 1 and the device 2, the device that has received the phase information calculates the distance through the operation in Equation (116) described above. In this way, it is possible to extract only the propagation delay component and perform accurate distance measurement even when the four-times repeated alternating sequence is adopted.
Note that
In
Subsequently, the device 1 executes carrier sensing for, for example, 128 μS (sec) following the transmission of the transmission wave A1 and thereafter transmits the transmission wave B1. After receiving the transmission wave B1, the device 2 executes carrier sensing for, for example, 128 μS (sec) and thereafter transmits the transmission wave B2. Furthermore, the device 2 transmits the transmission wave B2 again following the transmission of the transmission wave B2. After receiving the transmission wave B2 from the device 2, the device 1 executes carrier sensing for, for example, 128 μS (sec) and thereafter transmits the transmission wave B1.
On the other hand, in
Subsequently, the device 1 receives the transmission wave A2 from the device 2, thereafter executes carrier sensing for, for example, 128 μS (sec) and transmits the transmission wave B1. Note that the device 1 may transmit the transmission wave B1 so that the device 2 can receive the transmission wave B1 twice at timing of time t=T and t=t0+T. After receiving the transmission wave B1 twice, the device 2 executes carrier sensing for, for example, 128 μS (sec) and transmits the transmission wave B2.
As is obvious from a comparison between
Equation (98) described above showing the eight-times repeated alternating sequence holds in a system of residue in which a detected phase operation result is 2π, that is, a case where the detected phase is calculated in a range of 0 to 2π. When the left side of Equation (98) is assumed to be S8A and a certain integer is assumed to be n8A, the following Equation (99) holds:
S8A+n8A×2π=4(ωB1+ωB2)τ1 (99)
Equation (99) is modified into Equation (100) below:
(ωB1+ωB2)τ1=(S8A/4)+(n8A×π/2) (100)
Equation (100) described above shows that (ωB1+ωB2)τ1 has uncertainty of a π/2 cycle. That is, (ωB1+ωB2)τ1 is obtained in a system of residue of π/2.
Therefore, since τ1=(R/c), a maximum measurement distance that can be measured (hereinafter referred to as “maximum measurable distance”) in the eight-times repeated alternating sequence is 1/2 in the case where four waves are simultaneously transmitted and a distance is calculated from Equation (61) described above.
On the other hand, Equation (116) described above showing the four-times repeated alternating sequence also holds in a system of residue, the detected phase operation result of which is 2π, that is, a case where the phase is calculated in a range of 0 to 2π. When the left side of Equation (116) is assumed to be S4A and a certain integer is assumed to be n4A, the following Equation (117) holds:
(ωB1+ωB2)τ1=(S4A/2)+(n4A×π) (117)
Equation (117) described above shows that (ωB1+ωB2)τ1 has uncertainty at a period of π. That is, (ωB1+ωB2)τ1 is calculated as a system of residue of π.
Consequently, a maximum distance that can be measured (hereinafter referred to as “maximum measurable distance”) in the four-times repeated alternating sequence is two times the maximum measurable distance of the eight-times repeated alternating sequence and it is clear that the same maximum measurable distance as the maximum measurable distance in the case where the distance is calculated by Equation (61) described above.
A measurement result of a distance equal to or larger than the maximum measurable distance is similar to a measurement result of a short distance and it is hard to make distinction between the distances, and so the four-times repeated alternating sequence having a larger maximum measurable distance is advantageous over the eight-times repeated alternating sequence. Furthermore, the smaller the (ωB1+ωB2), the greater the maximum measurable distance becomes, but even when the value doubles in the four-times repeated alternating sequence, a maximum measurable distance equal to the maximum measurable distance of the eight-times repeated alternating sequence can be obtained. That is, the four-times repeated alternating sequence has an advantage that the number of combinations of available frequencies (channels) can be increased and measurement with a free channel can be made easier when it is only required to achieve the same maximum measurable distance as the maximum measurable distance of the eight-times repeated alternating sequence.
In this way, the present embodiment can achieve accurate distance measurement by causing carrier signals from the first device and the second device to be repeatedly alternated. In this case, use of the four-times repeated alternating sequence can shorten a communication time period necessary for distance measurement compared to the eight-times repeated alternating sequence. Moreover, compared to the eight-times repeated alternating sequence, the four-times repeated alternating sequence can increase twofold the maximum measurable distance and increase a degree of freedom of the operating frequency.
As shown in
In the four-times repeated alternating sequence of the first embodiment, a transmission time period of the device 1 is approximately twice the transmission time period of the device 2. Similarly, distance measurement can also be performed by making the transmission time period of the device 2 approximately twice the transmission time period of the device 1. The present embodiment shows an example in this case.
Equation (84) to Equation (87) described above obtained by taking into account time sequence transmission can be modified into the following Equations (118) to (121) respectively. That is, Equation (118) is the same equation as Equation (84).
Equation (119) is obtained by setting T to T=0 in Equation (85) and substituting t0 by 2t0. Furthermore, Equation (120) is obtained by adding a predetermined delay T to the left side of Equation (86). Similarly, Equation (121) is obtained by substituting t0 by 2t0 in Equation (87).
θH1(t)+θH2(t+t0)=θτH1+θτH2+{(ωB1−ωB2)+(ωC1−ωC2)}t0 (118)
θH1(t)+θH2(t+2t0)=θτH1+θτH2+2{(ωB1−ωB2)+(ωC1−ωC2)}t0 (119)
θL1(t+T)+θL2(t+t0+T)=θτL1+θτL2+{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (120)
θL1(t+T)+θL2(t+2t0+T)=θτL1+θτL2+2{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (121)
Next, calculating 2×Equation (118)−Equation (119)−{2×Equation (120)−Equation (121)} gives the following Equation (122):
θH1(t)+2θH2(t+t0)−θH2(t+2t0)−{θL1(t+T)+2θL2(t+t0+T)−θL2(t+2t0+T)}=(θτH1−θτL1)+(θτH2−θτL2)=2×(ωB1+ωB2)τ1 (122)
From Equation (122), τ1 can be obtained. That is, Equation (122) shows that accurate distance measurement can be achieved by removing distance estimation error factors as in the case of the four-times repeated alternating sequence in the first embodiment.
Furthermore, Equation (122) shows that phase measurement is performed a total of 6 times. That is, Equation (122) shows that it is possible to sequentially measure detected phase θH1(t) of the device 2 when time t=0, detected phase θH2(t+t0) of the device 1 when time t=t0, detected phase θH2(t+2t0) of the device 1 when time t=2t0, detected phase θL1(t+T) of the device 2 when time t=T, detected phase θL2(t+t0+T) of the device 1 when time t=t0+T, and detected phase θL2(t+2t0+T) of the device 1 when time t=2t0+T.
In this case, phases θH2(t+t0) and θH2(t+2t0) can be measured by a single transmission sequence, and phases θL2(t+t0+T) and θL2(t+2t0+T) can be measured by a single transmission sequence.
Furthermore, the control section 11 of the device 1 transmits a transmission wave having an angular frequency of ωC1−ωB1 at timing corresponding to t=T. The control section 21 of the device 2 transmits a transmission wave having an angular frequency of ωC2−ωB2 at timing corresponding to t=t0+T and t=2t0+T immediately after receiving the transmission wave.
Thus, as shown in
Furthermore, the control section 11 of the device 1 acquires phases θH2(t+t0) and θH2(t+2t0) on a basis of the received signals at time t=t0 and t=2t0, and acquires phases θL2(t+t0+T) and θL2(t+2t0+T) on a basis of the received signals at time t=t0+T and t=2t0+T.
One of the device 1 and the device 2 that have measured phases in the four-times repeated alternating sequence shown in
A communication sequence when distance measurement is performed by adopting the present embodiment corresponds to the length of an A1 period in
Furthermore, the maximum measurable distance in the four-times repeated alternating sequence according to the present embodiment is twice the maximum measurable distance in the eight-times repeated alternating sequence and it is obvious that the same maximum measurable distance as the maximum measurable distance in the case where the distance is calculated by Equation (61) described above.
In this way, the present embodiment can obtain effects similar to the effects in the first embodiment.
Note that wireless transmitting/receiving devices generally have greater transmission power consumption than reception power consumption. Therefore, according to the first embodiment, the device 1 has greater power consumption necessary for communication for distance measurement than the device 2, whereas according to the second embodiment, the device 2 has greater power consumption necessary for communication for distance measurement than the device 1. Therefore, it is possible to determine which of the first embodiment or the second embodiment should be adopted depending on which of the two devices 1 and 2 is the device, power consumption of which should be reduced. For example, when the device 1 is a fixed device and the device 2 is a battery-driven portable device or the like, the first embodiment in which power consumption of the device 2 is smaller is preferably adopted.
In the transmission sequence according to the present embodiment, as shown in
The value of 2×Equation (113)−Equation (112) obtained to obtain Equation (116) of the first embodiment and the value of 2×Equation (118)−Equation (119) obtained to obtain Equation (122) of the second embodiment have the same value (θτH1+θτH2).
Similarly, the value of 2×Equation (115)−Equation (114) obtained to obtain Equation (116) of the first embodiment and the value of 2×Equation (120)−Equation (121) obtained to obtain Equation (122) of the second embodiment have the same value (θτL1+θτL2).
Therefore, it is possible to obtain results similar to the results in Equation (116) and Equation (122) even by switching round {2×Equation (113)−Equation (112)} and {2×Equation (118)−Equation (119)} and using following Equation (116a) obtained using Equation (118), Equation (119), Equation (114) and Equation (115):
θH1(t)+2θH2(t+t0)−θH2(t+2t0)−{θL2(t+2t0+T)+2θL1(t+t0+T)−θL1(t+T)}=(θτH1−θτL1)+(θτH2−θτL2)=2×(ωB1+ωB2)τ1 (116a)
Similarly, it is also possible to obtain results similar to the results in Equation (116) and Equation (122) also by switching round {2×Equation (115)−Equation (114)} and {2×Equation (120)−Equation (121)} and using the following Equation (116b) obtained using Equation (112), Equation (113), Equation (120) and Equation (121):
θH2(t+2t0)+2θH1(t+t0)−θH1(t)−{θL1(t+T)+2θL2(t+t0+T)−θL2(t+2t0+T)}=(θτH1−θτL1)+(θτH2−θτL2)=2×(ωB1+ωB2)τ1 (116b)
In the example in
Furthermore, the control section 11 of the device 1 transmits a transmission wave having an angular frequency of ωC1−ωB1 at timing corresponding to t=T. The control section 21 of the device 2 transmits a transmission wave having an angular frequency of ωC2−ωB2 at timing corresponding to t=t0+T and t=2t0+T immediately after receiving the transmission wave.
In this way, as shown in
Furthermore, the control section 11 of the device 1 acquires phase θH2(t+2t0) on a basis of the received signal at time t=2t0 and acquires phases θL2(t+t0+T) and θL2(t+2t0+T) on a basis of the received signals at time t=t0+T and t=2t0+T.
It is possible to calculate a distance using Equation (116b) on a basis of these phases obtained at the devices 1 and 2.
In the example in
Furthermore, the control section 11 of the device 1 transmits a transmission wave having an angular frequency of ωC1−ωB1 at timing corresponding to t=T and t=t0+T.
The control section 21 of the device 2 transmits a transmission wave having an angular frequency of ωC2−ωB2 at timing corresponding to t=2t0+T immediately after receiving the transmission wave.
In this way, as shown in
Furthermore, the control section 11 of the device 1 acquires phases θH2(t+t0) and θH2(t+2t0) on a basis of the received signals at time t=t0 and t=2t0 and acquires phase θL2(t+2t0+T) on a basis of the received signal at time t=2t0+T.
It is possible to calculate a distance using Equation (116a) on a basis of the phases obtained at the devices 1 and 2.
Other components and operations are similar to the components and operations of the first and second embodiments.
Thus, the present embodiment can also obtain effects similar to the effects in the first and second embodiments.
As shown in
In Equation (98) showing the transmission sequence of
θH1(t)+2θH2(t+t0)+θH1(t+2t0)−{θL1(t+T)+2θL2(t+t0+T)+θL1(t+2t0+T)}=2{(θτH1−θτL1)+(θτH2−θτL2)}=4×(ωB1+ωB2)τ1 (98′)
Equation (98′) shows that in the six-times repeated alternating sequence, it is also possible to accurately measure a delay time τ1, that is, the distance between the devices 1 and 2 by adding up the phase differences obtained in the devices 1 and 2 as in the case of Equation (98) showing the aforementioned eight-times repeated alternating sequence.
Furthermore, the control section 11 of the device 1 transmits a transmission wave having an angular frequency of ωC1−ωB1 at timing corresponding to t=T. The control section 21 of the device 2 transmits a transmission wave having an angular frequency of ωC2−ωB2 at timing corresponding to t=t0+T immediately after receiving the transmission wave. The control section 11 of the device 1 transmits the transmission wave having an angular frequency of ωC1−ωB1 again at timing corresponding to t=2t0+T immediately after receiving the transmission wave.
As shown in
Furthermore, the control section 11 of the device 1 acquires phase θH2(t+t0) on a basis of the received signal at time t=t0 and acquires phase θL2(t+t0+T) on a basis of the received signal at time t=t0+T.
One of the device 1 and the device 2 that have measured phases in the six-times repeated alternating sequence transmits phase information acquired at the own device to the other of the device 1 and the device 2. Of the device 1 and the device 2, the device that has received the phase information calculates the distance through the operation in Equation (98′) described above. In this way, when the six-times repeated alternating sequence is adopted, it is also possible to extract only the propagation delay component and perform accurate distance measurement.
Note that the communication time period necessary for distance measurement in the six-times repeated alternating sequence is substantially the same as the communication time period necessary for distance measurement in the four-times repeated alternating sequence.
(Doubling of Maximum Measurable Distance)
In Equation (98′) showing the six-times repeated alternating sequence, equations similar to Equations (99) and (100) described above hold and a detectable maximum measurable distance becomes ½ of the detectable maximum measurable distance of the four-times repeated alternating sequence. However, it is possible to extend the maximum measurable distance to the same distance as the distance of the four-times repeated alternating sequence through a modification of the equation. Hereinafter, the method is described.
Calculating a difference between Equation (84) described above showing a case where after receiving a transmission wave from the device 1, the device 2 transmits the transmission wave to the device 1 and Equation (90) described above used for removing a distance estimation error factor gives the following Equation (101):
θH1(t)+θH2(t+t0)−θH1(t+t0+D)−θH2(t+D)=2{(ωB1−ωB2)+(ωC1−ωC2)}t0 (101)
Similarly, calculating Equation (86)−Equation (94) gives the following Equation (102):
θL1(t)+θL2(t+t0)−θL1(t+t0+D)−θL2(t+D)=2{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (102)
Even when a fixed delay T is added to t on the left side of Equation (102), the right side remains constant, and so Equation (103) is obtained.
θL1(t+T)+θL2(t+t0+T)−θL1(t+t0+D+T)−θL2(t+D+T)=2{−(ωB1−ωB2)+(ωC1−ωC2)}t0 (103)
Calculating Equation (101)−Equation (103) gives the following Equation (104):
θH1(t)+θH2(t+t0)−θH1(t+t0+D)−θH2(t+D)−θL1(t+T)−θL2(t+t0+T)+θL1(t+t0+D+T)+θL2(t+D+T)=4(ωB1−ωB2)t0 (104)
Assuming D=t0 in Equation (104) gives the following Equation (110):
θH1(t)−θH1(t+2t0)−θL1(t+T)+θL1(t+2t0+T)=4(ωB1−ωB2)t0 (110)
The result of Equation (110) is obtained in a system of residue of 2π. Substituting the left side of Equation (110) by S4 gives the following Equation (105) using an integer n4:
(ωB1−ωB2)t0=(S4/4)+(n4π/2) (105)
(ωB1−ωB2)t0 in Equation (105) has uncertainty at a period of π/2.
As design values of the device, if a local frequency for baseband is set to 5 [MHz], a frequency error between transmission and reception is set to maximum ±40 [ppm], and a delay t0 is set to 0.1 [ms], 360°×(5×106×±40 [ppm])=±7.2° is satisfied. That is, it is obvious that the left side of Equation (105) described above falls within a range of −π/4 to π/4 [rad]=−45 to 45° and it is thereby possible to exclude uncertainty. Therefore, the following Equation (111) is obtained using S4 calculated within a range of −π to π [rad]:
(ωB1−ωB2)t0=S4/4 (111)
In this way, it is possible to uniquely determine (ωB1−ωB2)t0 by Equation (111).
Substituting Equation (20), Equation (30), Equation (40) and Equation (50) into Equation (88) and assuming τ1=τ2 gives the following Equation (107):
θH1(t)+θH2(t+t0)−{θL1(t+T)+θL2(t+t0+T)}=2(ωB1+ωB2)τ1+2(ωB1−ωB2)t0 (107)
Since Equation (107) is obtained in a system of residue of 2π, assuming the value of the left side to be S6 gives the following Equation (108) using the integer n6:
(ωB1+ωB2)τ1=S6/2+(ωB1−ωB2)t0+n6π (108)
Since (ωB1−ωB2)t0 can be uniquely calculated from Equation (111), (ωB1+ωB2)τ1 can be calculated with uncertainty at a period of π by substituting Equation (111) into Equation (108).
That is, since τ1=(R/c), by calculating (ωB1−θB2)t0 from Equation (110) and Equation (111) instead of directly calculating Equation (98′) and substituting (ωB1−ωB2)t0 into Equation (107) and calculating (ωB1+ωB2)τ1, it is possible to extend the maximum measurable distance up to twice the eight-times repeated alternating sequence, that is, the same maximum measurable distance as in the case where the distance is calculated by Equation (61) described above in the same way as in the four-times repeated alternating sequence.
Obtaining Equation (110) requires θH1(t), θH1(t+2t0), θL1(t+T) and θL1(t+2t0+T) to be detected and obtaining Equation (107) requires θH1(t), θH2(t+t0), θL1(t+T) and θL2(t+t0+T) to be detected. That is, the equations show that it is possible to extend the measurable distance up to the maximum measurable distance of the four-times repeated alternating sequence by measuring phases in the six-times repeated alternating sequence shown in
In this way, the present embodiment adopts the six-times repeated alternating sequence, and can also perform accurate distance measurement and shorten a communication time period to approximately 6/8 times compared to the eight-times repeated alternating sequence. In the six-times repeated alternating sequence, it is also possible to extend the maximum measurable distance up to the same maximum measurable distance when a distance is calculated by Equation (61) described above.
(Generalizing of Transmission/Reception Frequency)
An example of generalizing of transmission/reception frequency is described.
(Generalizing of Frequency when Calculating Phases in Eight-Times Repeated Alternating Sequence at a Time)
When a transmission wave is ωc+ωB or ωc−ωB, Equation (84), Equation (20) and Equation (30) described above are obtained.
θH1(t)+θH2(t+t0)=θτH1+θτH2+{(ωB1−ωB2)+(ωC1−ωC2)}t0 (84)
θτH1=(ωC1+ωB1)τ1 (20)
θτH2=(ωC2+ωB2)τ2 (30)
When angular frequencies are generalized, transmission waves of the device 1 are assumed to be ωC1+ωH1 and ωC1+ωL1, angular frequencies of transmission waves of the device 2 are substituted by ωC2+ωH2 and ωC2+ωL2, the following Equations (123) to (130) hold. Note that a detected phase at the above generalized angular frequency is represented by Θ(t):
ΘH1(t)+ΘH2(t+t0)=ΘτH1+ΘτH2+(ωH1−ωH2)t0+(ωC1−ωC2)t0 (123)
ΘH1(t+t0+D)+ΘH2(t+D)=ΘτH1+ΘτH2−(ωH1−ωH2)t0−(ωC1−ωC2)t0 (124)
ΘL1(t+T)+ΘL2(t+t0+T)=ΘτL1+ΘτL2+(ωL1−ωL2)t0+(ωC1−ωC2)t0 (125)
ΘL1(t+t0+D+T)+ΘL2(t+D+T)=ΘτL1+ΘτL2−(ωL1−ωL2)t0−(ωC1−ωC2)t0 (126)
ΘτH1=(ωC1+ωH1)τ1 (127)
ΘτH2=(ωC2+ωH2)τ2 (128)
ΘτL1=(ωC1+ωL1)τ1 (129)
ΘτL2=(ωC2+ωL2)τ2 (130)
Therefore, an equation equivalent to Equation (98) is given by the following Equation (131):
Here, a design value of ωH1 and ωH2 is set to ωH and a design value of ωL1 and θL2 is set to ωL. When a target specification of the distance measuring system is taken into consideration, errors of ωH1 and ωH2 relative to ωH, and errors of ωL1 and ωL2 relative to ωL are on the order of several tens of [ppm], and using the design values poses no problem as long as the resolution is on the order of 1 m. The following Equation (134) is obtained by modifying Equation (131), assuming τ1=τ2, using ωH instead of ωH1 and ωH2 and using ωL instead of ωL1 and ωL2:
ΘH1(t)+ΘH2(t+t0)+ΘH1(t+t0+D)+ΘH2(t+D)−{ΘL1(t+T)+ΘL2(t+t0+T)+ΘL1(t+t0+D+T)+ΘL2(t+D+T)}≈4(ωH−ωL)τ1 (134)
It is possible to calculate τ1 by Equation (134) and calculate a distance using R=cτ1.
(Generalizing of Frequency when Dividing Phase Calculation in Eight-Times Repeated Alternating Sequence)
It has been described that in the eight-times repeated alternating sequence, the maximum measurable distance becomes ½ of the maximum measurable distance in the case where a distance is calculated by Equation (61), but it is possible to extend the maximum measurable distance up to the same distance in the case where the distance is calculated by Equation (61) by dividing phase calculation as in the case of the six-times repeated alternating sequence.
Equation (104) can be expressed using a generalized angular frequency as the following Equation (135):
ΘH1(t)+ΘH2(t+t0)−ΘH1(t+t0+D)−ΘH2(t+D)−ΘL1(t+T)−ΘL2(t+t0+T)+ΘL1(t+t0+D+T)+ΘL2(t+D+T)=2{(ωH1−ωL1)−(ωH2−ωL2)}t0 (135)
Since Equation (135) described above is calculated in a system of residue of 2π, the following Equation (136) is obtained using an integer m8 if the left side is substituted by Σ8:
{(ωH1−ωL1)−(ωH2−ωL2)}t0=(Σ8/2)+m8π (136)
Here, as design values of the device, if an angular frequency difference between ωH1 and ωL1, and an angular frequency difference between ωH2 and ωL2 are set to 2π×10 [MHz], a frequency error between transmission and reception is set to maximum ±40 [ppm], and a delay to is set to 0.1 [ms], 360°×(10×106×±40 [ppm])=±14.4° is satisfied, and so it is obvious that the left side of Equation (136) falls within a range of −π/2 to π/2 [rad]=−90 to 90° and it is thereby possible to exclude uncertainty. That is, the following Equation (137) is given using Σ8 calculated in a range of −π to π [rad]:
{(ωH1−ωL1)−(ωH2−ωL2)}t0=Σ8/2 (137)
In this way, {(ωH1−ωL1)−(ωH2−ωL2)} to can be uniquely calculated from Equation (137).
The equation corresponding to Equation (107) described above can be obtained as the following Equation (138) in the same way as when Equation (134) is derived:
It is possible to determine τ1 by substituting the result of Equation (137) into Equation (138) and calculate the distance from a distance R=cτ1. In this case, it is possible to obtain a maximum measurable distance twice the maximum measurable distance calculated by Equation (134) and extend the distance to the same maximum measurable distance calculated by Equation (61).
(Generalizing of Frequency when Dividing and Performing Phase Calculation in Six-Times Repeated Alternating Sequence)
When D=t0 is assumed in Equation (135) described above, the following Equation (139) is obtained:
ΘH1(t)−ΘH1(t+2t0)−ΘL1(t+T)−+ΘL1(t+2t0+T)=2{(ωH1−ωL1)−(ωH2−ωL2)}t0 (139)
When the result of calculating the left side of Equation (139) in a range of −π to π [rad] is substituted by Σ6, it is possible to remove uncertainty in the same way as in the description when Equation (137) described above is derived and the following Equation (140) is obtained:
{(ωH1−ωL1)−(ωH2−ωL2)}t0=Σ6/2 (140)
It is possible to determine τ1 by substituting Equation (140) into Equation (138) and calculate the distance from the distance R=cτ1.
(Generalizing of Frequency when Performing Phase Calculation in Four-Times Repeated Alternating Sequence at One Time)
Similarly, Equation (116) and Equation (122) described above can be expressed by the following Equation (141) and Equation (142) using the design values of angular frequencies ωH and ωL respectively:
ΘH2(t+2t0)+2ΘH1(t+t0)−ΘH1(t)+{ΘL2(t+2t0+T)+2ΘL1(t+t0+T)−ΘL1(t+T)}≈2(ωH−ωL)τ1 (141)
ΘH1(t)+2ΘH2(t+t0)−ΘH2(t+2t0)−{ΘL1(t+T)+2ΘL2(t+t0+T)−ΘL2(t+2t0+T)}≈2(ωH−ωL)τ1 (142)
(ωH−ωL)τ1 can be calculated with uncertainty at a period of π in the same way as in Equation (117). Therefore, by using Equation (141) or Equation (142), the four-times repeated alternating sequence is also applicable to distance measurement using arbitrary two, three or more waves.
In the present embodiment, as shown in
The following Equation (143) is obtained from Equation (141) described above using τ1=(R/c):
(½)×ΘH2(t+2t0)+2ΘH1(t+t0)−ΘH1(t)−{ΘL2(t+2t0+T)+2ΘL1(t+t0+T)−ΘL1(t+T)}≈(ωH−ωL)×(R/c) (143)
It is obvious that Equation (144) can be obtained through calculations in the same way as described so far.
(½)×ΘM2(t+2t0+D)+2ΘM1(t+t0+D)−ΘM1(t+D)−{ΘL2(t+2t0+T)+2ΘL1(t+t0+T)−ΘL1(t+T)}≈(ωM−ωL)×(R/c) (144)
In the three frequencies six-times repeated alternating sequence shown in
Furthermore, in the present embodiment, as shown in
Hereinafter, the reason that accurate distance measurement is possible by the three frequencies shortened alternating sequence of
The following four equations show Equation (27), Equation (37), Equation (47) and Equation (57) described above:
θH1(t)=−{(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2−θτH1} (27)
θH2(t)=(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2+θτH2 (37)
θL1(t)=−{(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)−θτL1} (47)
θL2(t)=(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)+θτL2 (57)
In Equation (27), Equation (37), Equation (47) and Equation (57), if the angular frequency of the transmission wave of the device 1 is substituted by ωC1+ωH1 and ωC1+ωL1, and the angular frequency of the transmission wave of the device 2 is substituted by ωC2+ωH2 and ωC2+ωL2 and the angular frequencies are generalized, the following Equations (201) to (204) hold using Equations (127) to (130):
ΘH1(t)=−{(ωC1−ωC2)t+(ωH1−ωH2)t+(ΘC1−ΘC2)+(ΘH1−ΘH2)−ΘτH1} (201)
ΘH2(t)=(ωC1−ωC2)t+(ωH1−ωH2)t+(ΘC1−ΘC2)+(ΘH1−ΘH2)+ΘτH2 (202)
ΘL1(t)=−{(ωC1−ωC2)t+(ωL1−ωL2)t+(ΘC1−ΘC2)+(ΘL1−ΘL2)−ΘτL1} (203)
ΘL2(t)=(ωC1−ωC2)t+(ωL1−ωL2)t+(ΘC1−ΘC2)+(ΘL1−ΘL2)+ΘτL2 (204)
Similarly, when the third angular frequencies ωC1+ωM1 and ωC2+ωM2 are used, it is obvious that the following Equation (205) and Equation (206) hold:
ΘM1(t)=−{(ωC1−ωC2)t+(ωM1−ωM2)t+(ωC1−ωC2)+(ΘM1(t)−ΘM2)−ΘτM1} (205)
ΘM2(t)=(ωC1−ωC2)t+(ωM1−ωM2)t+(ΘC1−ΘC2)+(ΘM1−ΘM2)+ΘτM2 (206)
where
ΘτM1=(ωC1+ωM1)τ1 (129a)
ΘτM2=(ωC2+ωM2)τ2 (130a)
From the relationship among Equation (201) to Equation (206) described above, the following Equation (207) to Equation (211) hold:
ΘH1(t)+ΘH2(t+2t0)=ΘτH1+ΘτH2+2{(ωC1−ωC2)+(ωH1−ωH2)}t0 (207)
ΘH1(t+t0)+ΘH2(t+2t0)=ΘτH1+ΘτH2+{(ωC1−ωC2)+(ωH1−ωH2)}t0 (208)
ΘL1(t+T)+ΘL2(t+2t0+T)=ΘτL1+ΘτL2+2{(ωC1−ωC2)+(ωL1−ωL2)}t0 (209)
ΘL1(t+t0+T)+ΘL2(t+2t0+T)=ΘτL1+ΘτL2+{(ωC1−ωC2)+(ωL1−ωL2)}t0 (210)
ΘM1(t+D)+ΘM2(t+t0+D)=ΘτM1+ΘτM2+{(ωC1−ωC2)+(ωM1−ωM2)}t0 (211)
Note that as described above, it is assumed that a plurality of oscillators in the device 1 are oscillating in synchronization with a common reference oscillating source and a plurality of oscillators in the device 2 are also oscillating in synchronization with a common reference oscillating source. In this case, ideal angular frequencies designated as design values are assumed to be ωH, ωL and ωM and a frequency error between transmission and reception is assumed to be k, the following Equation (212) holds:
k=(ωH1−ωH2)/ωH=(ωL1−ωL2)/ωL=(ωM1−ωM2)/ωM (212)
Using the k, the following Equation (213) and Equation (214) hold from Equation (207) to Equation (211):
As design values of the device, when k is set to maximum ±40 [ppm], ωH−ωL is set to 2π×10 [MHz] and delay t0 is set to 0.1 [ms], if the right side of Equation (213) is calculated, ±40 [ppm]×2π×10 [MHz]×0.1 [ms])=±0.08π is satisfied, and so the left side of Equation (213) can be uniquely determined without uncertainty of 2π. That is, even when k is on the order of ±40 [ppm], if transmission/reception parameters are appropriately selected, it is obvious that the uncertainty of 2π on the left side of Equation (213) can be excluded.
Thus, the following Equation (215) holds from Equation (213) and Equation (214):
ΘH1(t+t0)+ΘH2(t+2t0)−ΘM1(t+D)−ΘM2(t+t0+D)−(ωH+ωM)/(ωH−ωL){ΘH1(t)−ΘH1(t+t0)−ΘL1(t+T)+ΘL1(t+t0+T)}=(ΘτH1−ΘτM1)+(ΘτH2−ΘτM2)≈2(ωH−ωM)τ1 (215)
Similarly, the following Equation (216) holds from Equation (207) to Equation (211):
ΘL1(t+t0+T)+ΘL2(t+2t0+T)−ΘM1(t+D)−ΘM2(t+t0+D)−(ωL−ωM)/(ωH−ωL){ΘH1(t)−ΘH1(t+t0)−ΘL1(t+T)+ΘL1(t+t0+T)}=(ΘτL1−ΘτM1)+(ΘτL2−ΘτM2)≈2(ωL−ωM)τ1 (216)
Furthermore, the following Equation (217) holds from the relationship among Equation (201) to Equation (204):
ΘH2(t+2t0)+2ΘH1(t+t0)−ΘH1(t)−{ΘL2(t+2t0+T)+2ΘL1(t+t0+T)−ΘL1(t+T)}=(ΘτH1−ΘτL1)+(ΘτH2−ΘτL2)≈2(ωH−ωL)τ1 (217)
That is, using Equation (215), Equation (216) and Equation (217), it is obvious that distance measurement is also possible by a combination of any two of the three angular frequencies ωH, ωL and ωM.
Thus, in the present embodiment, distance measurement using three frequencies is possible using the method similar to the four-times repeated alternating sequence. Three ways of distance measurement are possible using the three frequencies six-times repeated alternating sequence. In the three frequencies shortened alternating sequence, a phase needs to be acquired only one time by the device 2 at the third frequency and the transmission time period of the device 1 can be shortened. Similarly, in the case of four or more waves, the transmission time period can be shortened likewise. Furthermore, Equation (213) can be obtained from the frequencies at which reception is performed twice each time and the frequencies need not be the initial two frequencies. One device (e.g., device 1) may “transmit/receive” with one of the two frequencies among three or more frequencies used. Since these can be easily analogized from above, and so description is omitted.
A sixth embodiment of the present invention is described. A hardware configuration in the present embodiment is similar to the hardware configuration of the first embodiment.
Each embodiment described above has described a method in which one of the device 1 and the device 2 transmits phase information on a basis of acquired I or Q signals to the other device, the other device synthesizes the phase information obtained at the devices 1 and 2 and calculates a distance. In this case, if the one of the devices 1 and 2 carries out data communication separately to acquire phase information measured by the other, a time period until completion of distance measurement may be extended to establish data communication or a protocol may become complicated. The present embodiment shows a specific example of enabling transmission of phase information from which such data communication is omitted.
As shown in
The device 2 is assumed to perform transmission by giving θD2H or θD2L as a phase offset without changing the radius 1 of the input. This corresponds to shifting the phase of the carrier signal to be transmitted. That is, when the device 2 performs transmission with an angular frequency of ωC2+ωB2, ITX2=cos(θD2H) and QTx2=sin(θD2H) are input and when the device 2 performs transmission with an angular frequency of ωC2−ωB2, ITx2=cos(θD2L) and QTx2=sin(θD2L) are input. Hereinafter, transmission/reception signals in the case is described.
First, phase detection with a transmission wave having a high angular frequency of ωC2+ωB2 is described. When initial phases of the angular frequencies ωC2 and ωB2 are assumed to be θC2 and θB2 respectively, a signal tx2(t) having an angular frequency of ωC2+ωB2 transmitted from the device 2 is expressed by the following Equation (301):
When the distance between the device 2 and the device 1 is set to R and a transmission wave from the device 2 is assumed to be received by the device 1 after a delay time τ2, the received signal rx1(t) is expressed by the following Equation (302):
rx1(t)=cos {(ωC2+ωB2)(t−τ2)+θC2+θB2−θD2H}=cos{(ωC2+ωB2)t+θC2+θB2−θD2H−θτH2} (302)
Note that θτH2=(ωC2+ωB2)τ2 (303)
Therefore, it can be easily analogized from a comparison between Equation (29) and Equation (30) described above and Equation (302) and Equation (303) that a phase θH2(t) detected by the device 1 is given by the following Equation (304) similar to Equation (37) described above:
θH2(t)=(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2+θD2H+θτH2 (304)
Phase detection with a transmission wave having a low angular frequency of ωC2−ωB2 is described. A phase θL2(t) detected by the device 1 can be calculated by the following Equation (305) in the same way as in the case of derivation of Equation (304) described above:
θL2(t)=(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)+θD2L+θτL2 (305)
where
θτL2=(ωC2−ωB2)τ2 (306)
Here, a case is considered where distance measurement is performed using the four-times repeated alternating sequence shown in
Assume that the distance between the device 1 and the device 2 is R and the delay time until the transmission wave of the device 1 arrives at the device 2 is τ1. If ITx1=1 and QTx1=0, detected phases θH1 (t) and θL1(t) at the device 2 are given by Equation (20), Equation (27), Equations (40) and (47) described above. These equations are shown again:
θτH1=(ωC1+ωB1)τ1 (20)
θH1(t)=−{(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2−θτH1} (27)
θτL1=(ωC1−ωB1)τ1 (40)
θL1(t)=−{(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)−θτL1} (47)
Here, it is analogized from Equation (116) described above that when the device 2 transmits phase information obtained from the received signal in addition to the initial phase to the device 1 and the device 1 can perform distance measurement with the phase information obtained from the received signal. Hereinafter, the analogy is examined.
The device 2 is assumed to set phase offsets θD2H and θD2L shown in the following Equation (307) and Equation (308) from the detected phase of the received signal:
θD2H=2θH1(t+t0)−θH1(t) (307)
θD2L=2θL1(t+t0+T)−θL1(t+T) (308)
The device 2 performs transmission using θD2H and θD2L calculated on a basis of the phase information obtained from the received signal. The device 1 adds up the two pieces of phase information obtained by the received signals at timings of t=2t0 and t=2t0+T in
Here, θD2H−θD2L is given by the following Equation (310):
Since a delay of the radio wave between the device 1 and the device 2 does not depend on the propagating direction of the radio wave, that is, τ1=τ2, the following Equation (311) holds from Equation (309) and Equation (310) described above:
θH2(t+2t0)−θL2(t+2t0+T)=(θτH1−θτL1)+(θτH2−θτL2)=2(ωB1+ωB2)τ1 (311)
Equation (311) means that distance measurement can be performed using only the phase information measured by the device 1. That is, it is clear that when the device 2 performs transmission using θD2H and θD2L given by Equation (307) and Equation (308) on a basis of the measured phase information, the device 1 can perform distance measurement using only the phase information measured by the device 1.
Thus, in the present embodiment, one of the devices 1 and 2 transmits to the other device a transmission wave by shifting the phase of a carrier signal to be transmitted with a phase obtained on a basis of measured phase information, and the other device can thereby perform distance measurement. In the present embodiment, this eliminates the necessity for separately communicating phase information and can prevent the time period until completion of distance measurement from lengthening or prevent the protocol from becoming complicated.
A modification of the sixth embodiment is described.
Equation (310) described above shows that Equation (310) also holds when the device 2 sets the phase offsets θD2H and θD2L shown by the following Equation (312) and Equation (313) from the detected phase of the received signal:
θD2H=0 (312)
θD2L=2θL1(t+t0+T)−θL1(t+T)−{2θH1(t+t0)−θH1(t)} (313)
Even when the device 2 transmits the transmission wave generated using θD2H and θD2L to the device 1, the device 1 can perform distance measurement using only the measured phase information.
In this way, what phases should be given at the time of transmission by the device 2 is a design item and even when the phases are modified in various ways, effects of the present embodiment can be obtained.
Furthermore, as is clear from Equation (102), similar effects can be obtained even when similar phase changes are given to θC2 or θB2. Here, the method for shifting the phase of a carrier signal to be transmitted has been described as phase information to be given to ITX2 and QTX2 on a basis of the configuration of the radio section shown in
Furthermore, using a similar approach, it is also possible to perform distance measurement in other transmission/reception sequences with only the phase information measured by the device 1. That is, the final phase of the transmission/reception sequence may be designated as transmission from the device 2 to the device 1, and when the device 2 performs transmission, the device 2 may carry out predetermined operation on a basis of the received phase information and transmit the result by shifting the phase of the device 2.
A seventh embodiment of the present invention is described. A hardware configuration of the present embodiment is similar to the hardware configuration of the first embodiment.
As described above, since it is not possible to detect a detected phase difference exceeding 2π, a plurality of distance candidates exist for the calculated detected phase difference. The aforementioned three frequencies six-times repeated alternating sequence of
When the transmission waves are ωC+ωB and ωC−ωB, if the device 2 transmits the transmission waves at an angular frequency of ωC2+ωB2, ITx2=cos(θD2H) and QTx2=sin(θD2H) are input as phase offsets and if the device 2 transmits the transmission waves at an angular frequency of ωC2−ωB2, ITx2=cos(θD2L) and QTx2=sin(θD2L) are input. The transmission/reception signal in the case is expressed by the equations described above which are shown again below:
θH1(t)=−{(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2−θτH1} (27)
θH2(t)=(ωC1−ωC2)t+(ωB1−ωB2)t+θC1−θC2+θB1−θB2+θD2H+θτH2 (304)
θL1(t)=−{(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)−θτL1} (47)
θL2(t)=(ωC1−ωC2)t−(ωB1−ωB2)t+θC1−θC2−(θB1−θB2)+θD2L+θτL2 (305)
θτH1=(ωC1+ωB1)τ1 (20)
θτH2=(ωC2+ωB2)τ2 (303)
θτL2=(ωC2−ωB2)τ2 (306)
θτL1=(ωC1−ωB1)τ1 (40)
In order to explain that distance measurement is possible at two arbitrary frequencies among three frequencies, an equation of distance measurement in a case where angular frequencies are generalized is described first.
When the angular frequencies of transmission waves of the device 1 are assumed to be ωC1+ωH1, ωC+ωL1 and ωC1+ωM1, the angular frequencies of transmission waves of the device 2 are assumed to be ωC2+ωH2, ωC2+ωL2 and ωC2+ωM2, and when the device 2 performs transmission at an angular frequency of ωC2+ωH2, ITx2=cos(ΘD2H) and QTx2=sin(ΘD2H) are input, and when the device 2 performs transmission at an angular frequency of ωC2+ωL2, ITx2=cos(ΘD2L) and QTx2=sin(ΘD2L) are input and when the device 2 performs transmission at an angular frequency of ωC2+ωM2, ITx2=cos(ΘD2M) and QTX2=sin(ΘD2M) are input. If calculations are performed in the same way as described so far, the following Equation (320) to Equation (332) hold. Note that ωH1>ωM1>ωL1 is assumed and the notation of the detected phase at the generalized angular frequency described above is assumed to be Θ(t):
ΘH1(t)+ΘH2(t+2t0)=ΘτH1+ΘτH2+ΘD2H+2{(ωH1−ωH2)+(ωC1−ωC2)}t0 (320)
ΘH1(t+t0)+ΘH2(t+2t0)=ΘτH1+ΘτH2+ΘD2H+{(ωH1−ωH2)+(ωC1−ωC2)}t0 (321)
ΘL1(t+T)+ΘL2(t+2t0+T)=ΘτL1+ΘτL2+ΘD2L+2{(ωL1−ωL2)+(ωC1−ωC2)}t0 (322)
ΘL1(t+t0+T)+ΘL2(t+2t0+T)=ΘτL1+ΘτL2+ΘD2L+{(ωL1−ωL2)+(ωC1−ωC2)}t0 (323)
ΘM1(t+D)+ΘM2(t+2t0+D)=ΘτM1+ΘτM2+ΘD2M+2{(ωM1−ωM2)+(ωC1−ωC2)}t0 (324)
ΘM1(t+t0+D)+ΘM2(t+2t0+D)=ΘτM1+ΘτM2+ΘD2M+{(ωM1−ωM2)+(ωC1−ωC2)}t0 (325)
ΘτH1=(ωC1+ωH1)τ1 (326)
ΘτH2=(ωC2+ωH2)τ2 (327)
ΘτL1=(ωC1+ωL1)τ1 (328)
ΘτL2=(ωC2+ωL2)τ2 (329)
ΘτM1=(ωC1+ωM1)τ1 (330)
ΘτM2=(ωC2+ωM2)τ2 (331)
Here, the device 2 sets phase offsets shown in the following Equation (332) to Equation (334) on a basis of the acquired phase information:
ΘD2H=2ΘH1(t+t0)−ΘH1(t) (332)
ΘD2L=2ΘL1(t+t0+T)−ΘL1(t+T) (333)
ΘD2M=2ΘM1(t+t0+D)−ΘM1(t+D) (334)
When the device 2 transmits transmission waves having the set phase offsets, calculating and organizing Equation (221)×2−Equation (220)−{Equation (223)×2×Equation (222)} described above gives the following Equation (335):
Here, even when the angular frequencies ωH1 and ωH2, and ωL1 and ωL2 are substituted by their respective design values ωH and ωL, if a target specification of the distance measuring system is taken into consideration, errors of ωH1 and ωH2 with respect to ωH and errors of ωL1 and ωL2 with respect to ωL are on the order of several tens of [ppm], and the substitution has no practical problem. Thus, assuming τ1=τ2, using ωH instead of ωH1 or ωH2, using ωL instead of ωL1 or ωL2 and modifying Equation (335) gives the following Equation (336):
ΘH2(t+2t0)−ΘL2(t+2t0+T)≈2(ωH−ωL)τ1 (336)
From Equation (336), τ1 is determined and the distance can be calculated from R=cτ1.
Similarly, calculating and organizing Equation (321)×2−Equation (320)−{Equation (325)×2−Equation (324)} and Equation (325)×2−Equation (324)−{Equation (323)×2−Equation (322)} gives the following Equation (337) and Equation (338):
where the angular frequency ωM are design values of angular frequencies ωM1 and ωM2.
Equation (336) to Equation (338) described above mean that the device 1 can perform distance measurement using only the phase information measured by the own device. That is, it is obvious that if the device 2 transmits a transmission wave using ΘD2H, ΘD2L and ΘD2M given by Equation (332) to Equation (334) on a basis of the measured phase information, the device 1 can perform distance measurement using only the phase information measured by the device 1.
In this way, according to the present embodiment, in the three frequencies six-times repeated alternating sequence, one of the devices 1 and 2 transmits to the other device, a transmission wave by shifting the phase of a carrier signal to be transmitted with a phase obtained on a basis of measured phase information, and the other device can thereby perform distance measurement without separately communicating the phase information, and it is possible to prevent a time period until completion of distance measurement from lengthening or prevent a protocol from becoming complicated.
Next, an eighth embodiment of the present invention is described. A hardware configuration of the present embodiment is similar to the hardware configuration of the first embodiment.
As described above, in the three frequencies six-times repeated alternating sequence, a three frequencies shortened alternating sequence shown in
Even when the three frequencies shortened alternating sequence is adopted, Equations (320) to (323) and Equations (326) to (329) described above hold. Moreover, the following Equation (339) also holds by using Equation (330) and Equation (331):
ΘM1(t+D)+ΘM2(t+t0+D)=ΘτM1+ΘτM2+ΘD2M+{(ωM1−ωM2)+(ωC1−ωC2)}t0 (339)
Note that as described above, a plurality of oscillators in the device 1 are assumed to be oscillating in synchronization with a common reference oscillating source and a plurality of oscillators in the device 2 are also assumed to be oscillating in synchronization with a common reference oscillating source. In this case, if ideal angular frequencies are assumed to be ωH, ωL and ωM, and a frequency error between transmission and reception is assumed to be k, the following Equation (340) holds:
k=(ωH1−ωH2)/ωH=(ωL1−ωL2)/ωL=(ωM1−ωM2)/ωM (340)
Here, the device 2 sets phase offsets shown in the following Equation (341) to Equation (343) on a basis of the acquired phase information:
ΘD2H=2ΘH1(t+t0)−ΘH1(t) (341)
ΘD2L=2ΘL1(t+t0+T)−ΘL1(t+T) (342)
ΘD2M=ΘM1(t+D)−{(ωM−ωL)/(ωH−ωL)}{ΘH1(t)−ΘH1(t+t0)}−{(ωH−ωM)/(ωH−ωL)}{ΘL1(t+T)−ΘL1(t+t0+T)} (343)
When the device 2 transmits a transmission wave having the set phase offset, it is obvious from a comparison between
ΘH1(t+t0)+ΘH2(t+2t0)−ΘM1(t+D)−ΘM2(t+t0+D)−{(ωH−ωM)/(ωH−ωL)}{ΘH1(t)−ΘH1(t+t0)−ΘL1(t+T)+ΘL1(t+t0+T)}=ΘτH1+ΘτH2+ΘD2H−{ΘτM1+ΘτM2+ΘD2M}+{(ωH1−ωH2)−(ωM1−ωM2)}t0−{(ωH−ωM)/(ωH−ωL)}{(ωH1−ωH2)−(ωL1−ωL2)}t0 (344)
Substituting Equation (340), Equation (341) and Equation (343) into Equation (344) described above gives the following Equation (345):
ΘH1(t+t0)+ΘH2(t+2t0)−ΘM1(t+D)−ΘM2(t+t0+D)−{(ωH−ωM)/(ωH−ωL)}{ΘH1(t)−ΘH1(t+t0)−ΘL1(t+T)+ΘL1(t+t0+T)}=ΘτH1+ΘτH2−(ΘτM1+ΘτM2)+{(ωH1−ωH2)−(ωM1−ωM2)}t0−{(ωH−ωM)/(ωH−ωL)}{(ωH1−ωH2)−(ωL1−ωL2)}t0+2ΘH1(t+t0)−ΘH1(t)+{(ωM−ωL)/(ωH−ωL)}{ΘH1(t)−ΘH1(t+t0)}+{(ωH−ωM)/(ωH−ωL)}{ΘL1(t+T)−ΘL1(t+t0+T)}−ΘM1(t+D) (345)
Organizing the above equation using τ1=τ2 gives the following Equation (346):
ΘH2(t+2t0)−ΘM2(t+t0+D)=(ΘτH1−ΘτM1)+(ΘτH2−ΘτM2)≈2(ωH−ωM)τ1 (346)
Calculating Equation (339)−Equation (323)−{(ωM−ωL)/(ωH−ωL)}{Equation (320)−Equation (321)−Equation (322)+Equation (323)} gives the following Equation (347):
ΘM1(t+D)+ΘM2(t+t0+D)−ΘL1(t+t0+T)−ΘL2(t+2t0+T)−{(ωM−ωL)/(ωH−ωL)}{ΘH1(t)−ΘH1(t+t0)−ΘL1(t+T)+ΘL1(t+t0+T)}=ΘτM1+ΘτM2+ΘD2M−{ΘτL1+ΘτL2+ΘD2L}+{(ωM1−ωM2)−(ωL1−ωL2)}t0−{(ωM−ωL)/(ωH−ωL)}{(ωM1−ωM2)−(ωL1−ωL2)}t0 (347)
Substituting Equation (340), Equation (342) and Equation (343) into Equation (347) described above gives the following Equation (348):
ΘM1(t+D)+ΘM2(t+t0+D)−ΘL1(t+t0+T)−ΘL2(t+2t0+T)−{(ωM−ωL)/(ωH−ωL)}{ΘH1(t)−ΘH1(t+t0)−ΘL1(t+T)+ΘL1(t+t0+T)}=ΘτM1+ΘτM2−(ΘτL1+ΘτL2)+{(ωM1−ωM2)−(ωL1−ωL2)}t0−{(ωM−ωL)/(ωH−ωL)}{(ωM1−ωM2)−(ωL1−ωL2)}t0+{(ωM−ωL)/(ωH−ωL)}{ΘH1(t)−ΘH1(t+t0)}−{(ωH−ωM)/(ωH−ωL)}{ΘL1(t+T)−ΘL1(t+t0+T)}+ΘM1(t+D)−2ΘL1(t+t0+T)+ΘL1(t+T) (348)
Organizing the above equation using τ1=τ2 gives the following Equation (349):
ΘM2(t+t0+D)−ΘL2(t+2t0+T)=(ΘτM1−ΘτL1)+(ΘτM2−ΘτL2)≈2(ωM−ωL)τ1 (349)
Equation (336), Equation (346) and Equation (349) described above mean that the device 1 can perform distance measurement using only the phase information measured by the own device. That is, it is obvious that if the device 2 transmits a transmission wave using ΘD2H, ΘD2L and ΘD2M given by Equation (341) to Equation (343) on a basis of the measured phase information, the device 1 can perform distance measurement using only the phase information measured by the device 1.
Thus, according to the present embodiment, in the three frequencies shortened alternating sequence, one of the devices 1 and 2 transmits to the other device a transmission wave by shifting the phase of a carrier signal to be transmitted with a phase obtained on a basis of measured phase information, and the other device can thereby perform distance measurement without separately communicating the phase information, and it is possible to prevent a time period until completion of distance measurement from lengthening or prevent a protocol from becoming complicated.
In
As shown in
A data transmitting/receiving section 37 is provided in the vehicle control device 35. The data transmitting/receiving section 37 can perform wireless communication with the data transmitting/receiving section of the key 31 via an antenna 35a. The data transmitting/receiving section 37 receives the peculiar data transmitted from the key 31 and transmits predetermined response data to the key 31 and perform authentication with the key 31 and the automobile 32.
The data transmitting/receiving section 37 can finely set electric field intensity. The authentication is not performed unless the key 31 is located in a relatively close position where the key 31 is capable of receiving transmission data of the data transmitting/receiving section 37, that is, near the automobile 32.
For example, as indicated by a broken line in
In
Therefore, in the present embodiment, the control section 36 determines on a basis of the authentication result of the data transmitting/receiving section 37 and a distance measurement result from the second device 2 whether unlocking and locking, a start of the engine, and the like are permitted.
The first device 1 in the respective embodiments is incorporated in the key 31. On the other hand, the second device 2 in the respective embodiments is mounted on the vehicle control device 35. A transmission wave from the device 1 is received in the device 2 via an antenna 27a. A transmission wave from the device 2 is received in the device 1 via the antenna 27a. The transmission wave from the device 1 is directly received by the antenna 27a in some case and is received by the antenna 27a through the relay devices 33 and 34 in other cases. Similarly, the transmission wave from the device 2 is directly received by the device 1 from the antenna 27a in some cases and is received by the device 1 from the antenna 27a through the relay devices 33 and 34.
When it is assumed that phases of the transmission waves from the device 1 and the device 2 do not change in the relay devices 33 and 34, the device 2 can calculate a distance from the key 31 on a basis of the phases calculated in the devices 1 and 2. The device 2 outputs the calculated distance to the control section 36. A distance threshold for permitting authentication of the key 31 is stored in the memory 38. When the distance calculated by the device 2 is within the distance threshold read out from the memory 38, the control section 36 assumes that the key 31 is authenticated and permits unlocking and locking, a start of the engine, and the like. When the distance calculated by the device 2 is greater than the distance threshold read out from the memory 38, the control section 36 does not permit the authentication of the key 31. Therefore, in this case, the control section 36 does not permit unlocking and locking, a start of the engine, and the like.
Note that the relay devices 33 and 34 can change the phases of the transmission waves from the device 1 and the device 2. Even in this case, since initial phases of the devices 1 and 2 are unknown, the relay devices 33 and 34 cannot calculate a phase shift amount necessary for keeping the distance calculated by the device 2 within the distance threshold read out from the memory 38. Therefore, even if the relay devices 33 and 34 are used, possibility that the authentication of the key 31 is permitted is sufficiently small.
As explained above, in the present embodiment, by using the distance measuring system in the respective embodiments, it is possible to prevent unlocking and the like of the vehicle from being performed by relay attack to the smart entry system.
Note that the present invention is not limited to the above-described embodiments, but can be modified in various ways without departing from the spirit and scope of the present invention in an implementation phase. For example, in
Furthermore, the above-described embodiments include inventions in various phases and various inventions can be extracted according to appropriate combinations in a plurality of disclosed configuration requirements. For example, even when some configuration requirements are deleted from all the configuration requirements shown in the embodiments, configurations from which the configuration requirements are deleted can be extracted as inventions when the effects described in the field of the effects of the invention can be achieved.
While certain embodiments have been described, these embodiments have been presented by way of example only, and are not intended to limit the scope of the inventions. Indeed, the novel devices and methods described herein may be embodied in a variety of other forms; furthermore, various omissions, substitutions and changes in the form of the embodiments described herein may be made without departing from the spirit of the inventions. The accompanying claims and their equivalents are intended to cover such forms or modification as would fall within the scope and spirit of the inventions.
Number | Date | Country | Kind |
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2018-010400 | Jan 2018 | JP | national |
2018-020766 | Feb 2018 | JP | national |
This application is a continuation of application Ser. No. 16/687,855 filed on Nov. 19, 2019, which is a continuation of application Ser. No. 15/923,169 filed on Mar. 16, 2018 (now U.S. Pat. No. 10,502,808) and is based upon and claims the benefit of priority from the prior Japanese Patent Applications No. 2018-010400 filed on Jan. 25, 2018 and No. 2018-020766 filed on Feb. 8, 2018; the entire contents of which are incorporated herein by reference.
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Number | Date | Country | |
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20210356548 A1 | Nov 2021 | US |
Number | Date | Country | |
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Parent | 16687855 | Nov 2019 | US |
Child | 17388459 | US | |
Parent | 15923169 | Mar 2018 | US |
Child | 16687855 | US |