JP2012237103A - Smart system and mobile unit for smart system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a smart system having a new technology of prohibiting relay of an RA relay of a relay station attack.SOLUTION: The smart system includes: an in-vehicle system 10 that transmits a vehicle-side signal including predetermined vehicle-side data by radio; and a mobile unit 20 that determines whether the vehicle-side data included in the vehicle-side signal is valid or not on receipt of the vehicle-side signal, spread-modulates mobile-side data with a predetermined spread code when the data is determined to be valid, to transmit a mobile-side signal based on the spread modulation signal after spread modulation by radio. The in-vehicle system 10 spread-demodulates the mobile-side signal to obtain the mobile-side data, determines whether the obtained mobile-side data is valid or not, and unlocks a door when the data is determined to be valid. The mobile unit 20 adds a false signal which has not been spread-demodulated with the predetermined spread code to the mobile-side signal.

Description

  The present invention relates to a smart system and a portable device of the smart system.

  Conventionally, as shown in FIG. 12A, when a user 91 of a vehicle 90 has a portable device 92 and approaches the vehicle 90, a vehicle-side signal transmitted from the vehicle 90 is received by the portable device 92, and the portable device 92. Transmits the mobile side signal to the vehicle 90 based on the reception of the vehicle side signal, and the vehicle 90 performs smart driving (unlocking the door of the vehicle 90 based on the reception of the mobile side signal). And smart system technology for performing vehicle drive start and / or start. The receivable range 93 of the vehicle side signal transmitted from the vehicle 90 is limited to the vicinity of the vehicle 90, and smart driving is not realized when the portable device 92 is far away from the vehicle 90. ing.

  In contrast to such smart system technology, even when the portable device 92 is far away from the vehicle 90, communication between the portable device 92 and the vehicle 90 is realized using a repeater, and the vehicle 90 is smartly driven. The relay station attack to be performed may be a problem.

  In the relay station attack, as shown in FIG. 12 (b), the RA repeater 94 is arranged in the communicable range 93 of the vehicle side signal, the RA repeater 95 is arranged in the vicinity of the portable device 95, and the vehicle 90 Is received by the RA repeater 94, converted into an uplink repeater signal and transmitted to the RA repeater 95. The RA repeater 95 receives the uplink repeater signal and returns it to the vehicle signal. The data is transmitted to the portable device 92. Further, RA repeaters 96 and 97 for relaying the portable side signal are arranged in the vicinity of the portable device 92 and the vehicle 90, respectively, and the RA repeater 96 receives the portable side signal transmitted from the portable device 92. It is converted into a downlink relay signal and transmitted to the RA repeater 97, and this downlink relay signal is received by the RA repeater 97, returned to the portable side signal, and transmitted to the vehicle 90.

  As a countermeasure against such a relay station attack in which the RA repeater intervenes in the smart system, Patent Document 1 discloses that the RA repeater intervenes, the output level of the RA repeater, and the RARA repeater-vehicle distance. A technique is described in which when the power of the radio wave received on the vehicle side deviates from a specified range due to the change, it is determined that the RA repeater intervention is performed and smart driving is prohibited.

JP 2006-319846 A

  However, in the above measures, when the RA repeater 97 has a function of adjusting the output level of the signal to be relayed, the received power on the vehicle side can be within the specified range. Unable to detect RA repeater intervention.

  SUMMARY OF THE INVENTION In view of the above points, the present invention provides a new technique for prohibiting relaying by an RA relay, and an object of the present invention is to support an RA relay capable of adjusting the output level of a signal to be relayed.

  In order to achieve the above object, an invention according to claim 1 is a smart system that performs one or both of unlocking a vehicle door and starting a vehicle drive device as a smart drive, and is installed in the vehicle. The vehicle-mounted system (10) and a portable device (20) carried by the user, the vehicle-mounted system (10) wirelessly transmits a vehicle-side signal including predetermined vehicle-side data, and the portable device (20 ) Is based on having received the said vehicle side signal, determining whether the said vehicle side data contained in the said vehicle side signal are regular, and having determined that it is regular Mobile-side data is spread-modulated with a predetermined spreading code, the mobile-side signal based on the spread-modulation signal after spread modulation is wirelessly transmitted, and the in-vehicle system (10) spreads and demodulates the mobile-side signal, Mobile side Data is acquired, and it is determined whether or not the acquired mobile-side data is authentic, and based on the determination that the acquired mobile-side data is authentic, the smart drive is performed, and the portable device (20) Comprises false signal output means (28) for outputting a false signal which is a signal not spread-modulated with the predetermined spreading code, and the false signal output by the false signal output means (28) and the spread modulation signal are A smart system characterized in that the portable side signal is generated and wirelessly transmitted so as to be included.

  As described above, in the smart system using the spread spectrum method in transmitting the portable-side signal from the portable device (20) to the in-vehicle system (10), the portable device (20) uses a predetermined spreading code used for the spread spectrum method. A pseudo signal that is not spread-modulated is added to the portable side signal.

  In the absence of an RA repeater, this false signal is despread in the in-vehicle system (10) and distributed over a wide frequency band, so that the in-vehicle system (10) Mobile-side data can be correctly extracted from the signal to be synthesized.

  However, if the RA repeater is interposed in the transmission of the portable side signal from the portable device (20) to the in-vehicle system (10), the RA repeater that does not perform despread demodulation demodulates the portable side signal and converts it into a logical value (logical value). ), The data is not correct due to interference with false signals. Then, since the modulated signal obtained by modulating the incorrect data is sent to the other RA repeater, the data obtained as a result of reception, demodulation, and despread demodulation is not normal in the in-vehicle system (10). The relay station attack fails. Therefore, the relay station attack can be prevented regardless of whether or not the RA repeater can adjust the output level of the signal to be relayed.

  According to a second aspect of the present invention, in the smart system according to the first aspect, the false signal voltage output by the false signal adding means (28) is the false signal for generating the portable side signal. The voltage is higher than the voltage of a normal signal to be combined with the signal. By doing so, an appropriate false signal can be added.

According to a third aspect of the present invention, in the smart system according to the second aspect, the false signal adding means (28) includes an oscillator (28) that outputs a sine wave signal having a predetermined frequency, and the oscillator A signal based on the sine wave signal output by (28) is added to the portable side signal, and the amplitude of the sine wave output from the oscillator (28) is V _N and the frequency is f _N. When the amplitude of the normal signal is V _S and the bit rate is f _bit ,
V _N cos (2πf _N × t)> V _S Formula (1)
(1 / f _N ) × (φ _N / 2π) × 2> 1 / f _bit
phi _N is the phase of _V N cos satisfying the equation _{(1) (2πf N t)} , and satisfies the 0 ≦ φ _N ≦ π. In this way, a false signal having an appropriate frequency and intensity can be added.

  According to a fourth aspect of the present invention, in the smart system according to the first or second aspect, the false signal adding means (28) outputs a sine wave signal having a predetermined frequency for demodulating the vehicle side signal. An output oscillator (28) is provided, and a signal based on the sine wave signal output from the oscillator (28) is added to the portable side signal as the false signal. In this way, by using the oscillator (28) for demodulating the vehicle-side signal for generating a false signal, the component cost of the portable device (20) can be suppressed.

  Further, the invention according to claim 5 is the smart system according to any one of claims 1 to 4, wherein the portable device (20) is included in the in-vehicle system (10) among the portable side signals. The false signal is added to a portion excluding a portion including a bit used for synchronization acquisition or synchronization holding. By doing in this way, in synchronization acquisition or synchronization maintenance that is weaker to interference than despreading, synchronization acquisition or synchronization maintenance can be performed without failure due to false signals.

  According to a sixth aspect of the present invention, in a smart system that performs either or both of unlocking a vehicle door and starting a vehicle drive device as a smart drive, the portable device is carried by a user of the vehicle. An in-vehicle system (10) that wirelessly transmits a vehicle-side signal including predetermined vehicle-side data and performs smart driving based on determining that the data obtained by spreading and demodulating the received portable-side signal is legitimate. ) To determine whether the vehicle-side data included in the vehicle-side signal is normal, based on the reception of the vehicle-side signal, and based on determining that it is normal Basic transmission / reception means (21-27) for wirelessly transmitting portable side signals based on spread modulation signals after spreading modulation, and carrying side modulation of portable side data with a predetermined spreading code; And a false signal output means (28) for outputting a false signal which is a signal not spread-modulated with a spreading code, and the basic transmitting / receiving means (21 to 27) output the false signal output means (28). In the portable device, the portable-side signal is generated and wirelessly transmitted so that the false signal and the spread modulation signal are included. As described above, the feature of the present invention can also be understood as the feature of the portable device of the smart system.

  In addition, the code | symbol in the bracket | parenthesis in the said and the claim shows the correspondence of the term described in the claim, and the concrete thing etc. which illustrate the said term described in embodiment mentioned later. .

It is a block diagram of the smart system which concerns on 1st Embodiment of this invention. It is a figure which shows the outline | summary of a smart system and a relay station attack. It is a figure which shows the detail of the action | operation of RA repeater 96,97. It is a figure which shows the characteristic of the signals A, B, and C in RA repeater 96. It is a simulation result when the voltage of a normal signal and a false signal is made the same. It is a simulation result when the voltage of a false signal is made higher than that of a normal signal. It is a simulation result at the time of using the false signal of a preferable frequency. It is a simulation result at the time of using the signal based on a DC signal as a false signal. It is a simulation result at the time of using a false signal of 134 kHz. It is a figure which illustrates the bit structure of a regular signal. It is a block diagram of the smart system in the other example of this invention. It is a figure for demonstrating a relay station attack.

  Hereinafter, an embodiment of the present invention will be described. FIG. 1 shows a configuration of a smart system according to the present embodiment. This smart system unlocks a vehicle door and starts a vehicle drive device (for example, an engine) as a smart drive, and includes an in-vehicle system 10 mounted on a vehicle and a portable device 20 carried by a user. I have.

  The in-vehicle system 10 includes a vehicle-side control unit 11, a front end / modulator 12, an LF transmission antenna 13, an RF reception antenna 14, a front end / BPSK demodulator 15, a despreading unit 16, and the like.

  The portable device 20 includes an LF reception antenna 21, an amplifier / filter unit 22, an LF demodulation unit 23, a portable side control unit 24, a spreading unit 25, a BPSK modulator 26, an RF transmission antenna 27, an oscillator 28, and the like.

  Hereinafter, the operation of the entire smart system will be described together with the operation of each part of the in-vehicle system 10 and the portable device 20.

  First, the vehicle side control part 11 is comprised with a known microcomputer, and waits until transmission timing comes. As the transmission timing, there are a polling timing that visits regularly (for example, every 1 second), and a timing at which an operation in which the user touches the door is detected using a touch sensor (not shown).

  When the transmission timing arrives, the vehicle side control unit 11 creates predetermined LF data (corresponding to an example of portable side data) and outputs it to the front end / modulator 12. Then, the front end modulator 12 generates a signal in the LF wave band (corresponding to an example of a portable signal) including the LF data by performing processing such as modulation, amplification, and filtering on the received LF data. And output to the LF transmitting antenna 13. Thereby, the signal of the LF wave band is wirelessly transmitted from the LF transmission antenna 13. Since the signal of the LF wave band is strongly attenuated by the distance, it can be received only in the receivable area 50 (for example, a position within 1 meter from the vehicle) very close to the vehicle.

  As shown in FIG. 2A, when the portable device 20 held by the user 91 of the vehicle is in the receivable area 50, the signal of the LF wave band transmitted from the in-vehicle system 10 as described above is LF. The receiving antenna 21 receives wirelessly. The LF waveband signal wirelessly received by the LF receiving antenna 21 is input to the amplifier / filter unit 22, and the amplifier / filter unit 22 performs amplification and frequency filtering of the LF waveband signal.

  The signal in the LF wave band after being amplified and frequency-filtered is input to the LF demodulator 23. The LF demodulator 23 demodulates the input signal in the LF wave band, thereby the LF wave band. LF data included in the signal is acquired, and the acquired LF data is input to the portable control unit 24.

  The portable-side control unit 24 is configured by a known microcomputer, and determines whether or not the LF data input from the LF demodulating unit 23 is normal by a known method (for example, whether it matches the normal data). If it is determined that the data is not legitimate, the RF data described later is not transmitted, and the LF data is discarded.

  In the case of this example, since the portable device 20 corresponds to the in-vehicle system 10, it is determined that the LF data included in the LF waveband signal transmitted from the in-vehicle system 10 is genuine. In that case, the mobile-side control unit 24 creates predetermined RF data (corresponding to an example of mobile-side data) and inputs it to the diffusion unit 25.

  The spreader 25 is a circuit (for example, a microcomputer, FPGA) that performs spread spectrum modulation (more specifically, direct spread spectrum (DSSS)) and performs predetermined modulation on input RF data. A spread modulation signal (corresponding to an example of a normal signal) obtained by performing spread modulation with a spread code is input to the BPSK modulator 26.

  The BPSK modulator 26 performs BPSK modulation (or another modulation method) on the input modulation signal, and further amplifies and frequency filters the signal after BPSK modulation, and the resulting RF waveband (For example, about 300 MHz in Japan and North America, about 400 MHz in Europe and South Korea, which corresponds to an example of a portable signal) is input to the RF transmitting antenna 27. Then, the RF transmission antenna 27 wirelessly transmits the input RF waveband signal.

  The LF reception antenna 21, the amplifier / filter unit 22, the LF demodulation unit 23, the portable side control unit 24, the spreading unit 25, the BPSK modulator 26, and the RF transmission antenna 27 constitute an example of basic transmission / reception means.

  However, a false signal output from the oscillator 28 is added to the spread modulation signal input from the spreading unit 25 to the BPSK modulator 26. The oscillator 28 is a known oscillation circuit that outputs a sine wave signal having a predetermined frequency (N hertz). Therefore, the BPSK modulator 26 receives a composite signal of the spread modulation signal (normal signal) output from the spreading unit 25 and the false signal output from the oscillator 28, and the BPSK modulator 26 receives the composite signal. The above processing is performed and input to the RF transmission antenna 27.

  Therefore, the signal of the RF wave band transmitted wirelessly from the RF transmission antenna 27 includes a normal signal including RF data and a false signal output from the oscillator 28. This RF waveband signal reaches farther than the LF waveband signal.

  When such a signal in the LF wave band is transmitted from the portable device 20, the RF receiving antenna 14 of the in-vehicle system 10 wirelessly receives the signal in the RF wave band and inputs the signal to the front end / BPSK demodulator 15. Then, the front-end BPSK demodulator 15 performs processing such as amplification and frequency filtering on the input RF waveband signal, and further performs BPSK demodulation (or BPSK modulator 26 uses the processed RF waveband signal. If modulation is performed using a modulation scheme other than BPSK, demodulation corresponding to the modulation scheme is performed, and the resulting signal is input to the despreading section 16.

  The despreading unit 16 is a circuit (for example, a microcomputer, FPGA) that performs spread spectrum demodulation (more specifically, direct spread spectrum (DSSS)), and is input from the front end / BPSK demodulator 15. The acquired signal is subjected to synchronization acquisition, synchronization tracking, and despreading demodulation processing using the same predetermined spreading code as the spreading unit 25.

  The signal input to the despreading unit 16 corresponds to a composite signal of a false signal and a regular signal, but the false signal of this composite signal is not a signal that has been spread-modulated with the predetermined spreading code. As a result, only the regular signal of the combined signal is restored as RF data by the despread demodulation. The despreading unit 16 inputs the RF data restored in this way to the vehicle-side control unit 11.

  When this RF data (corresponding to an example of portable data) is input, the vehicle-side control unit 11 checks the RF data with a predetermined collation in order to determine whether or not the RF data is authentic. Check with the data. Then, based on the result of the collation, whether or not the RF data is genuine is determined by a known method (for example, whether or not the key data matches the collation data).

  Since the portable device 20 that has transmitted an RF waveband signal including RF data is compatible with the in-vehicle system 10, this RF data is determined to be legitimate. And when it determines with it being a regular person, the vehicle side control part 11 starts a smart drive. Specifically, the actuator for the engine is controlled based on the fact that the door of the vehicle is unlocked by controlling an actuator (not shown) and the engine is started by the user (for example, pressing the engine start button). The engine is started by controlling (injector, igniter, starter motor, etc.). If the received RF waveband signal is not from the portable device 20, it is determined that the received RF data is not genuine, and smart driving is prohibited.

  As described above, when an RA repeater is not interposed, even if an RF waveband signal including a false signal is transmitted from the portable device 20, the false signal is despread in the in-vehicle system 10 and distributed over a wide frequency band. Therefore, the in-vehicle system 10 can correctly extract the mobile side data from the regular signal (the signal that is combined with the false signal to generate the mobile side signal).

  Here, a case where a relay station attack is attempted will be described. In the relay station attack to be prevented by the present embodiment, as shown in FIG. 2B, the RA repeater 94 is disposed within the communicable range 50 of the LF waveband signal, and the RA repeater 95 is installed in the portable device. 20, the LF waveband signal transmitted from the in-vehicle system 10 is received by the RA repeater 94, converted to an RF waveband signal and transmitted to the RA repeater 95, and the RF waveband signal is transmitted. The RA repeater 95 receives the signal, returns it to the LF waveband signal, and transmits it to the portable device 20.

  Further, RA repeaters 96 and 97 for relaying signals in the RF wave band (portable side signal) are arranged in the vicinity of the portable device 20 and the in-vehicle system 10 respectively, and the portable side signal transmitted from the portable device 20 is arranged. The RA repeater 96 receives and converts it into a downlink relay signal and transmits it to the RA repeater 97. The RA repeater 97 receives this downlink relay signal, returns it to the portable side signal and transmits it to the vehicle. Yes.

  Here, the details of the operation of the RA repeaters 96 and 97 that relay the RF waveband signal from the portable device 20 to the in-vehicle system 10 will be described with reference to FIG.

  An RF waveband signal A (BPSK modulated wave) transmitted from the portable device 20 is wirelessly received by the receiving antenna 96a of the RA repeater 96 and input to the front end 96b, and the front end 96b amplifies the input signal. And frequency filtering, and the resulting signal is input to the BPSK demodulator 96c. The BPSK demodulator 96c performs BPSK demodulation on the input signal and inputs the resulting signal B to the binarizer 96d. . The binarizing unit 96d binarizes the signal depending on whether the voltage of the input signal B is higher or lower than a predetermined threshold, and inputs the resulting signal C to the modulating unit 96e. The modulation unit 96e modulates the input signal C, converts it to an RF waveband signal, and inputs the signal to the transmission antenna 96f. Then, the transmitting antenna 96f wirelessly transmits the input RF waveband signal.

  Then, in the RA repeater 97, the RF waveband signal transmitted from the RA repeater 96 is wirelessly received by the receiving antenna 97a and input to the front end 97b, and the front end 97b amplifies and frequency-converts the input signal. Filtering is performed, and the resultant signal is input to the demodulation unit 97c. The demodulation unit 97c performs demodulation (demodulation corresponding to the modulation scheme of the modulation unit 96a of the RA repeater 96) on the input signal, and the result Is input to the binarization unit 97d. The binarization unit 97d binarizes the signal depending on whether the voltage of the input signal is higher or lower than a predetermined threshold (for example, 0 volts), and inputs the resultant signal to the BPSK modulation unit 97e. The BPSK modulation unit 97e modulates the input signal, converts it to an RF waveband signal, and inputs the signal to the transmission antenna 97f. Then, the transmission antenna 97f wirelessly transmits the input RF waveband signal, and the in-vehicle system 10 receives the RF waveband signal.

  FIG. 4 illustrates the waveforms of the signals A, B, and C when the false signal as described above is not included in the RF waveband signal transmitted by the portable device 20 and when it is included. . First, a case where the above-described false signal is not included in the RF waveband signal transmitted by the portable device 20 will be described. In this case, as shown in the upper part of FIG. 4, the frequency characteristic 51 of the signal A (the signal received by the receiving antenna 96a of the RA repeater 96) has an intensity in a wide frequency band because the signal A is spread-modulated. Is distributed.

  The time-voltage characteristic 52 of the signal B after the signal A is BPSK demodulated by the BPSK demodulator 96c via the receiving antenna 96b and the front end 96b of the RA repeater 96 is a portable device (however, the oscillator 28 is provided as usual). The signal after the BPSK spread modulation. Accordingly, the time-logical value (HI or LO) characteristic 53 of the signal C obtained by binarizing the signal B by the binarizing unit 96d is also the same as the spread-modulated RF data.

  On the other hand, when an RF waveband signal A including a composite signal of a false signal and a regular signal is transmitted from the portable device 20 as in the present embodiment, as shown in the lower part of FIG. The characteristic 54 includes a component whose intensity is distributed over a wide frequency band corresponding to a normal signal (a signal obtained by spreading and modulating RF data), and a component 54a whose intensity peaks at a specific frequency corresponding to a false signal. , 54b. Here, the frequencies of the peak components 54a and 54b are shifted from the center frequency of the normal signal by BPSK modulation by the output frequency (N hertz) of the oscillator 28.

  When such a signal A is BPSK demodulated by the BPSK demodulator 96c via the receiving antenna 96b and the front end 96b of the RA repeater 96, the time-voltage characteristic 55 of the signal B after BPSK demodulation is obtained after the BPSK spread modulation. It has a characteristic in which a sine wave of a false signal is combined with a regular signal. Therefore, the time-logic value (HI or LO) characteristic 56 of the signal C obtained by binarizing the signal B by the binarizing unit 96d, for example, with 0 volt as a threshold value is disturbed by a false signal component. The spread modulated RF data is not the same.

  Therefore, such a signal C is modulated by the modulation unit 96a and transmitted by the transmission antenna 96f, and received, demodulated, binarized and BPSK modulated by the RA repeater 97 as described above, and transmitted to the in-vehicle system 10. However, since an RF waveband signal including an incorrect value at the time of the signal C only reaches the portable device 20, the portable device 20 receives the RF waveband signal, performs BPSK demodulation, despread demodulation, Even if the control unit 11 obtains the data of the despreading demodulation, since this data is not regular LF data, the smart drive is prohibited, the door is not opened, and the engine is not started, so the relay station attack fails. To do.

  Hereinafter, details of the false signal output from the oscillator 28 will be described. First, the signal strength of the false signal will be described. The input power (corresponding to N) of the false signal is the S / N ratio that can be demodulated on the portable device 20 side in relation to the power of the normal signal (corresponding to N) combined with this false signal. Is set to be For example, if the combination of the portable device 20 and the in-vehicle system has a performance that can be demodulated to an S / N ratio of −20 dB, the false signal may be power having an upper limit of +20 dB with respect to the regular signal. However, the level is actually lowered below +20 dB in consideration of noise from the propagation environment.

  Further, in the case where the maximum value of the voltage of the false signal is equal to that of the normal signal, the false signal and the normal signal (generated randomly) are combined, and the resultant composite signal is binarized with 0 volt as a threshold value. The result of having performed is shown in FIG. In this simulation, the frequency of the false signal is 1 kHz, and the chip rate of the regular signal is 100 kcps.

  In this case, as shown in FIG. 5, the signal (d) obtained by binarizing the combined signal (c) of the false signal (a) and the normal signal (b) is the same as the normal signal (b). That is, even if a false signal is added, the error becomes 0, and the signal C in FIG. 3 becomes the same as the RF data spread-modulated by the portable device 20.

  If the false signal voltage is higher than in the example of FIG. 5, an error occurs. For example, when the voltage of the false signal is 1.1 times higher than the voltage of the normal signal, a simulation is performed in which the false signal and the normal signal are combined and the resultant combined signal is binarized with 0 volts as a threshold value. The results are shown in FIG. Other conditions of this simulation are the same as the simulation of FIG.

  In this case, as shown in FIG. 6, the signal (d) obtained by binarizing the synthesized signal (c) of the false signal (a) and the normal signal (b) is different from the normal signal (b). More specifically, the error rate is 12.5%. Therefore, the lower limit of the false signal voltage (intensity) is the voltage of the normal signal. That is, by adding a false signal, the signal C in FIG. 3 becomes a value different from the RF data generated by the portable device 20. As described above, the output voltage of the false signal needs to be higher than the output voltage of the normal signal to be synthesized.

  However, precisely, in the vehicle system 10, errors can be avoided even if the signal input to the communication unit 16 is slightly wrong with respect to the regular signal after being spread-modulated by the portable device 20 by despreading (spread spectrum). There is a case. For example, if half of one bit of RF data is wrong, the wrong part becomes 0 by despreading (sum), and if the correct part is obtained by despreading, a correct value is obtained. Further, the above simulation is an ideal system, and actually affects the design and product quality of the front end / BPSK demodulator 15 and the despreading unit 16 of the in-vehicle system 20. For example, if the amplitude fluctuates due to substrate noise, there is a high possibility that data different from RF data will be obtained by despreading even when the value is correct.

  From the above, the output voltage of the false signal needs to be higher than the output voltage of the normal signal to be synthesized, but in practice, it is set to a voltage that can not be demodulated after the RA repeater intervenes.

  Next, the frequency of the false signal will be described. As described above, even if a part of 1 bit (100 chips when the number of spreading codes used is 100) is erroneously binarized in the RA repeater 96, the in-vehicle system 10 may be able to demodulate. . Therefore, although one bit originally has the logical values of chips 0 and 1 as spreading codes, it is not essential that all the bits become 1 or 0, but it is preferable.

If the amplitude of the false signal is V _N , the frequency is f _N , the amplitude of the normal signal is V _S , and the bit rate is f _bit , then the voltage of the false signal exceeds the voltage of the normal signal,
V _N cos (2πf _N × t)> V _S Formula (1)
Must be satisfied (t is time). In addition, in order that the time when the voltage of the false signal exceeds the voltage of the normal signal exceeds the time of 1 bit, (1 / f _N ) × (φ _N / 2π) × 2> 1 / f _bit (2)
However, phi _N is the phase of _V N cos satisfying the equation _{(1) (2πf N t)} , it is necessary to satisfy the inequality that satisfy 0 ≦ φ _N ≦ π.

These expressions (1) and (2) define the frequency and voltage for making one bit wrong by a false signal. In order to prevent the normal signal from being restored in the binarization of the RA repeater 96 when the false signal is superimposed on the normal signal, the period of V _N ≦ V _S must exceed 1 bit. If the period satisfying this condition is 0 to φ _N (0 ≦ φ _N ≦ π), it exists twice during one period of the false signal, so the time is (1 / f _N ) × (φ _N / 2π ) × 2.

The frequency f _{N of the} false signal is calculated from the above two formulas (1) and (2). Therefore, when V _S = 1V, V _N = 2V, and f _bit = 1 kbps, for example, φ _N = π / 3 and f _N = 1000/3 Hz may be set.

  FIG. 7 shows the result of the same simulation as in FIGS. 5 and 6 for this example (the display format is the same as FIGS. 5 and 6). The other conditions of the simulation are the same as the simulation of FIG.

  In this case, as shown in FIG. 7, the signal (d) obtained by binarizing the synthesized signal (c) of the false signal (a) and the normal signal (b) always has a period of HI or LO that is the reciprocal of the bit rate (that is, 1 msec) or more.

  In an extreme example, in order to satisfy the above two inequalities, an example in which the frequency of the false signal is 0 hertz is possible. In this case, the false signal is a DC signal.

  FIG. 8 shows the result of the same simulation as in FIG. 7 for this example (the display format is also the same as FIG. 7). The other conditions for the simulation are the same as the simulation of FIG. In this case, as shown in FIG. 7, the signal (d) obtained by binarizing the synthesized signal (c) of the false signal (a) and the regular signal (b) always has a HI for 1 msec.

  In addition, as a method of using a false signal as a DC signal, for example, the oscillator 28 may be replaced with a circuit that outputs a DC signal. Alternatively, the oscillator 28 may be eliminated, and the RF carrier generated by the BPSK modulator 26 of FIG. 1 may be combined with the output result of the BPSK modulator 26. In the latter case, the phases of the RF carrier used as the false signal and the RF carrier used in the RF modulator are matched. This is because if these phases are shifted by (π / 2) + M × 180 ° (M is an integer), the DC component is lost.

  As described above, there is no lower limit of the frequency of the false signal (DC may be used), and a frequency satisfying the two inequalities (1) and (2) is preferable. In this way, a false signal having an appropriate frequency and intensity can be added.

  The frequency of the false signal output from the oscillator 28 may be, for example, the frequency of the LF carrier (134 kHz) used by the LF demodulator 23 to demodulate the LF waveband signal. In this case, the LF demodulator 23 may demodulate a signal in the LF wave band using the LF carrier (a sine wave signal having a predetermined frequency) output from the oscillator 28. In this way, by using the oscillator 28 for demodulating the signal in the LF waveband for generating a false signal, the component cost of the portable device 20 can be suppressed. FIG. 9 shows the result of the same simulation as in FIGS. 5 and 6 for this example (the display format is the same as FIGS. 5 and 6). The signal after binarization becomes different from the normal signal. The other conditions of the simulation are the same as the simulation of FIG.

  Next, timing for synthesizing a false signal with a regular signal will be described. The pseudo signal from the oscillator 28 may be combined with all the bits of the regular signal (the signal output from the spreading unit 25) obtained by spreading the RF data. In this case, the oscillator 28 only needs to output a false signal during operation of the portable device 20.

  Alternatively, the pseudo signal may be synthesized only for the remaining part without synthesizing the pseudo signal for a part of the regular signal. For example, in the normal signal 61 (one small square corresponds to 1 bit) as shown in FIG. 10, the first 2 bits 62 are synchronization acquisition bits, and the 8th and 9th bits 63 are synchronized. Suppose that it is a bit for. That is, the synchronization holding interval is 5 bits.

  In this case, the despreading unit 16 of the in-vehicle system 10 performs synchronization capture using the synchronization capture bit 62, performs synchronization retention using the synchronization retention bit 63, and performs despread demodulation using other bits. .

  Then, the oscillator 28 does not synthesize a false signal with respect to the synchronization acquisition bit 62 and the synchronization holding bit 63, and synthesizes a false signal only with other bits. In order to realize this, the portable control unit 24 (or the diffusion unit 25) controls on / off of the output of the false signal from the oscillator 28.

  Since synchronization acquisition and synchronization retention are less susceptible to noise than data demodulation (despreading) in accordance with the synchronization timing, this makes it difficult for synchronization acquisition or synchronization retention to be more disturbing than despreading due to spurious signals. Synchronization acquisition or synchronization maintenance can be performed without any problem.

  As described above, in the present embodiment, the portable device 20 generates and wirelessly transmits an RF waveband signal so that the false signal and the spread modulation signal output from the oscillator 28 serving as the false signal output unit are included.

  As described above, in the smart system that uses the spread spectrum method in transmitting the portable-side signal from the portable device 20 to the in-vehicle system 10, the portable device 20 is a pseudo signal that is not spread-modulated with a predetermined spread code used in the spread spectrum method. Add signal to mobile side signal.

  When the RA repeater is not interposed, the false signal is despread in the in-vehicle system 10 and is distributed over a wide frequency band. Therefore, the in-vehicle system 10 generates a regular signal (a signal that is combined with the false signal to generate the portable signal). ) Mobile side data can be extracted correctly.

  However, if an RA repeater intervenes in the transmission of the portable side signal from the portable device 20 to the in-vehicle system 10, when the RA repeater that does not perform despread demodulation demodulates the portable side signal and converts it into a data, It is obstructed and cannot make correct data. Since the modulated signal obtained by modulating the incorrect data is sent to the other RA repeater, the in-vehicle system 10 finally determines that the data obtained as a result of reception, demodulation, and despread demodulation is not normal. Relay station attack fails. Therefore, the relay station attack can be prevented regardless of whether or not the RA repeater can adjust the output level of the signal to be relayed.

(Other embodiments)
As mentioned above, although embodiment of this invention was described, the scope of the present invention is not limited only to the said embodiment, The various form which can implement | achieve the function of each invention specific matter of this invention is included. It is. For example, the following forms are also acceptable.

  (1) In the above embodiment, the pseudo signal output from the oscillator 28 and the normal signal output from the spreader 25 and input to the BPSK modulator 26 are combined into a combined signal, and this combined signal is converted into BPSK. The signal is input to the modulator 26.

  However, the false signal may be synthesized at the subsequent stage of the BPSK modulator 26 instead of being synthesized at the previous stage of the BPSK modulator 26 as described above. For example, as shown in FIG. 11, the portable device 20 further includes an amplifier 29 and a BPSK modulator 30. The sine wave signal output from the oscillator 28 is input to the amplifier 29, and is amplified to a desired voltage by the amplifier 29. A signal is input to the BPSK modulator 30, a sine wave signal (corresponding to a false signal) that has been subjected to BPSK modulation by the BPSK modulator 30 in the same manner as the BPSK modulator 26, and a normal signal output from the BPSK modulator 26 ( The RF data is spread-modulated and a signal obtained as a result of BPSK modulation or the like is synthesized, and the synthesized signal may be wirelessly transmitted as an RF waveband signal by the RF transmission antenna 27. In this case, the oscillator 28, the amplifier 29, and the BPSK modulator 30 constitute an example of the false signal output unit 28.

  Even in such an example, the portable device 20 is the same in that it generates an RF waveband signal (portable signal) and transmits it wirelessly so that the false signal and the spread modulation signal output from the false signal output means 28 are included. is there.

  (2) In the above embodiment, the false signal is a sine wave signal, a direct current signal, or a signal obtained by BPSK modulation of any one of the sine wave signal and the direct current signal. However, the false signal is not limited to such a signal, and may be any signal as long as the signal is not subjected to spread modulation with a spread code used for spread modulation of RF data.

  For example, a rectangular signal having higher power (or higher voltage) than the normal signal may be synthesized as a false signal with a normal signal obtained by spreading and modulating RF data. Even in this case, the RA repeater 96 binarizes in accordance with the signal with the larger power (or voltage), so the relay station attack fails.

Further, the pseudo signal combined with the regular signal is a signal that is spread-modulated with a spread code (hereinafter referred to as spread code Y) different from the spread code (hereinafter referred to as spread code X) used for spread modulation of RF data. There may be. Also in this case, if the power (or voltage) of the pseudo signal spread-modulated with the spreading code Y is higher than the power (or voltage) of the normal signal spread-modulated with the spreading code X, the RA repeater 96 Will be binarized according to the signal with the higher power (or voltage), so the relay station attack will fail. On the other hand, the in-vehicle system 10 despreads and demodulates the received RF waveband signal with the spread code X, so the signal spread-modulated with the spread code Y can be discarded and correct RF data can be acquired. The in-vehicle system 10 may be configured to despread and demodulate the received RF waveband signal with the spreading code X, and separately despread and demodulate the received RF waveband signal with the spreading code Y. In this case, the in-vehicle system 10 can correctly receive both the RF data included in the regular signal and the data included in the false signal.

  (3) In the above-described embodiment, smart driving is realized by performing one round-trip communication between the in-vehicle system 10 and the portable device 20, but smart driving is performed by performing round-trip round-trip communication. It may be realized. That is, (a) the in-vehicle system 10 transmits an LF waveband signal including predetermined LF data to the portable device 20. (B) “The portable device 20 determines whether or not the LF data included in the LF waveband signal is normal, and if it is normal, the RF waveband signal includes predetermined RF data. Is transmitted to the in-vehicle system 10, and the in-vehicle system 10 determines whether or not the RF data included in the signal of the RF waveband is normal, and if it is normal, the LF including predetermined LF data is transmitted. The process of “transmitting a waveband signal to the portable device 20” is repeated J times (where J is an integer of 1 or more). (C) The portable device 20 determines whether or not the LF data included in the LF waveband signal is normal. If the LF data is normal, the portable device 20 determines an RF waveband signal including predetermined RF data. The in-vehicle system 10 determines whether or not the RF data included in the signal of the RF waveband received for the J + 1th time is normal, and if it is normal, the smart drive is performed. Do. You may perform the process.

  In this case, a false signal may be included in the RF waveband signal transmitted from the portable device 20 to the in-vehicle system 10 in all of the multiple round trips. The false signal may be included in the RF waveband signal only in the first and last).

  (4) In the above embodiment, the smart drive is for unlocking the door of the vehicle and starting the vehicle drive device, but the smart drive is for unlocking only the door of the vehicle. Alternatively, only the vehicle drive device may be started.

  (5) Moreover, in the said embodiment, although the signal of LF wave band is used as the vehicle side signal transmitted by radio | wireless from the vehicle-mounted system 10 to the portable device 20, the radio signal of bands other than LF wave band is used. May be used. Similarly, as a portable signal wirelessly transmitted from the portable device 20 to the in-vehicle system 10, an RF waveband signal is used, but a radio signal in a band other than the RF waveband may be used. .

DESCRIPTION OF SYMBOLS 10 In-vehicle system 11 Vehicle side control part 12 Front end modulator 13 LF transmission antenna 14 RF reception antenna 15 Front end BPSK demodulator 16 Despreading part 20, 92 Portable device 21 LF reception antenna 22 Amplifier / filter part 23 For LF Demodulation unit 24 Portable side control unit 25 Spreading unit 26 BPSK modulator 27 RF transmission antenna 28 Oscillator 29 Amplifier 30 BPSK modulator 50, 93 Communication range 51, 54 Frequency characteristics 52, 55 of signal A Time-voltage characteristics of signal B 53, 56 Time-logical value characteristics 54a, 54b of signal C Peak component 61 Regular signal 62 Synchronization acquisition bit 63 Synchronization holding bit 90 Vehicle 91 User 94-97 RA repeater 96a, 97a Receiving antenna 96b, 97b Front end 96c BPSK demodulator 96d, 97d 2 Section 96e modulation unit 96f, 97f transmitting antenna 97c demodulator

Claims (6)

A smart system that performs one or both of unlocking a vehicle door and starting a vehicle drive device as a smart drive,
An in-vehicle system (10) mounted on a vehicle, and a portable device (20) carried by a user;
The in-vehicle system (10) wirelessly transmits a vehicle side signal including predetermined vehicle side data,
The portable device (20) determines whether the vehicle-side data included in the vehicle-side signal is normal based on the reception of the vehicle-side signal, and is normal Based on the determination, the portable side data is spread and modulated with a predetermined spreading code, the portable side signal based on the spread modulation signal after the spread modulation is wirelessly transmitted,
The in-vehicle system (10) acquires the mobile side data by spreading and demodulating the mobile side signal, determines whether or not the acquired mobile side data is normal, and is normal Based on the determination, perform the smart drive,
The portable device (20) includes a false signal output means (28) for outputting a false signal that is a signal not spread-modulated with the predetermined spreading code, and the false signal output by the false signal output means (28). And a mobile system for generating and transmitting the portable side signal so that the spread modulation signal is included. The voltage of the false signal output from the false signal adding means (28) is higher than a voltage of a normal signal combined with the false signal to generate the mobile-side signal. Smart system.
By doing so, an appropriate false signal can be added. The false signal adding means (28) includes an oscillator (28) that outputs a sine wave signal of a predetermined frequency, and the signal based on the sine wave signal output by the oscillator (28) is transferred to the portable signal. Added to the side signal,
When the amplitude of the sine wave output from the oscillator (28) is V _N , the frequency is f _N , the amplitude of the normal signal is V _S , and the bit rate is f _bit ,
V _N cos (2πf _N × t)> V _S Formula (1)
(1 / f _N ) × (φ _N / 2π) × 2> 1 / f _bit
The φ _N is a phase of V _N cos (2πf _N × t) that satisfies the formula (1), and satisfies 0 ≦ φ _N ≦ π. system.   The false signal adding means (28) includes an oscillator (28) that outputs a sine wave signal having a predetermined frequency for demodulating the vehicle-side signal, and is based on the sine wave signal output by the oscillator (28). The smart system according to claim 1, wherein the received signal is added to the portable side signal as the false signal.   The portable device (20) adds the false signal to a portion excluding a portion including a bit used for synchronization acquisition or synchronization retention in the in-vehicle system (10) in the portable side signal. The smart system according to any one of claims 1 to 4. In a smart system that performs any one or both of unlocking a vehicle door and starting a vehicle drive device as a smart drive, a portable device carried by a user of the vehicle,
From the in-vehicle system (10) for performing smart driving based on determining that the data obtained by spreading and demodulating the received portable side signal is legitimate while wirelessly transmitting a vehicle side signal including predetermined vehicle side data, Based on the reception of the vehicle-side signal, it is determined whether or not the vehicle-side data included in the vehicle-side signal is normal, and based on the determination that the vehicle-side data is normal, Basic transmission / reception means (21-27) for wirelessly transmitting portable-side signals based on spread-modulated signals after spreading-modulating side data with a predetermined spreading code;
A false signal output means (28) for outputting a false signal which is a signal not spread-modulated with the predetermined spreading code,
The basic transmission / reception means (21-27) generates the portable-side signal so as to include the false signal output from the false signal output means (28) and the spread modulation signal, and wirelessly transmits the portable signal. Machine.

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