JP2004211358A - Detector and lock control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a detector of simple constitution capable of positively detecting a user's intention as early as possible regarding the detector for detecting the intention of the user who is going to open a door, to form a trigger of automatic unlocking in an entry system for a vehicle, for instance. <P>SOLUTION: A handle mounting part 41 is provided with a radio type sensor 30 which turns on detection output respectively when a user's hand approaches the outside of a flap 42 in the natural position, when the flap 42 of a door handle is operated outside from the natural position being pulled by the user and when the flap 42 returns into the natural position from the outside operated position being pulled by the user. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a lock control device that performs automatic unlocking by detecting a user's intention to open a locked door, for example, in a vehicle entry system, and a detection device therefor.
[0002]
[Prior art]
In recent years, in vehicle entry systems, bidirectional communication has been performed between the portable device carried by the user and the main unit installed in the vehicle, etc. Have been proposed and some have been put to practical use.
In such a two-way communication type, an answer signal including a necessary code is automatically transmitted from the portable device to the main device in response to a request signal (for example, a start signal for activating the portable device) transmitted from the main device. Since transmission is possible, operations such as automatic unlocking can be realized without any operation by the user. For example, in a vehicle entry system, when a user carrying a portable device merely approaches a door of a specific vehicle equipped with a corresponding main body device, the two-way communication is established and the door lock is locked. An unlocking command is automatically output to the device, and a function of automatically unlocking the vehicle door (hereinafter, referred to as an automatic unlocking function) becomes possible. In addition, a more convenient entry system that realizes the unlocking or locking operation of the vehicle door basically without requiring the user's conscious operation is a development of a general keyless entry system, There is a growing need in the market for what is called a passive entry system (or a smart entry system) to increase the commercial value of vehicles.
[0003]
Such a passive entry system transmits a request signal from the main unit only when necessary and saves the battery power of the vehicle when a contact with a door handle or the like of a user's hand is detected. In addition, there is known a configuration in which the request signal is transmitted on the assumption that the user's intention to unlock is detected. As a sensor for detecting a contact of a user's hand with a door handle or the like, an optical sensor or a capacitance sensor has been conventionally used.
For example, Patent Literature 1 discloses a keyless entry device that transmits a request signal when a human body is detected by a capacitance sensor provided on a door handle.
Patent Document 2 discloses a keyless entry device that receives an ID from a portable device and performs collation when a user's intention to unlock is detected by an unlock intention detecting means (an operation switch or a capacitance sensor). Is disclosed.
[0004]
[Patent Document 1]
JP-A-10-308148
[Patent Document 2]
JP-A-2000-179211
[0005]
[Problems to be solved by the invention]
However, the above-described conventional keyless entry device has the following problems.
(B) When the door lock actuator is operated to the unlocking side by the automatic unlocking function while the user is pulling the door handle to open the locked door, the mechanical structure of the door lock mechanism is changed. This causes the gear in the door lock mechanism to be caught and the door cannot be unlocked.In this case, the user must release his / her hand from the door handle to open the door, and then touch the door handle again. It was necessary to extend the door handle to operate it, and if it was frequent, it was judged that it was a failure or had a discomfort, which was a problem.
As described above, the phenomenon that the door lock actuator operates during the operation of the door handle is caused by a conventional device that uses an optical sensor or a capacitance sensor as a sensor for detecting a user's intention to unlock. Especially easy to happen. As will be described later, the optical sensor and the capacitance sensor are easily affected by the surrounding environment and the detection area is small, so that the detection operation is delayed even though the user's hand is approaching. This is because the operation of moving the door lock actuator to the unlocking side after the verification of the authentication code from the operation is also delayed, and the possibility that the door lock actuator is finally activated while the door handle is being pulled is relatively high.
[0006]
(B) Optical sensors that are easily affected by dirt and foreign matter (for example, dead leaves) and capacitance sensors that are easily affected by dielectrics such as water are used to detect the user's intention to unlock. Therefore, depending on the surrounding environment (raindrops or dust), there is a possibility that this sensor does not operate at all, and a problem that the automatic unlocking function does not work at all even when the user operates the door handle may occur. In this case, it is necessary for the user to restart the operation of the door handle (operation for detecting the intention to unlock) until the automatic unlocking function is activated or to perform the unlocking operation using a physical key, but this is frequently performed. This is also a problem because it may be judged that a malfunction has occurred and the user may feel uncomfortable.
[0007]
In order to solve the above-mentioned problem (a), when the communication with the portable device is established and the ID collation results in a match, the operation of the door handle is detected by the handle operation detecting means. A technology is disclosed in which a drive control means for temporarily unlocking the door lock mechanism when unlocking is detected when the door lock mechanism is unlocked is detected. However, in this case, a handle operation detecting means for detecting the handle operation must be separately provided, which is disadvantageous in terms of cost and installation space, and has disadvantages in that control processing is complicated.
Further, Patent Document 2 described above discloses a configuration in which a switch operated by a user is provided near a door handle as a means for detecting a user's intention to unlock. The possibility of the occurrence of the problem (b) hardly occurs. However, since the switch must be provided in a limited space around the door handle, there is a disadvantage that the switch is disadvantageous in terms of cost, installation space, and freedom of vehicle design.
Accordingly, the present invention provides a detection device having a simple configuration capable of detecting a user's intention to open an opening / closing unit provided with a handle as early and reliably as possible, and a lock control device using the detection device. It is an object.
[0008]
[Means for Solving the Problems]
The detection device of the present application detects a user's intention to open an opening / closing unit provided with a handle (for example, a flap-type handle) having a movable unit (for example, a flap) that moves outward by a pull operation by a user. Detection device,
Radio waves for turning on the detection output when the movable portion is pulled outward by the user from the natural position and moves outward, and when the movable portion returns to the natural position from the position where the movable portion is outwardly moved by the user. It consists of a sensor of the formula.
Here, the "opening / closing unit" may be a door (door of a vehicle or a house) through which a person enters or exits, or a door through which luggage or the like other than a person enters or exits (for example, a trunk of a vehicle). The “natural position” means a position where no external force is applied (initial position).
Further, the detection function as described above can be realized by setting the detection area of the radio wave sensor to a specific range. For example, by configuring the radio wave sensor to transmit a radio wave from the inside to the outside of the movable part, by setting the detection area of the radio wave sensor to the inside of the movable part in a state of being pulled out to the maximum. It becomes possible.
[0009]
According to this configuration, as long as the failure of the sensor or the like does not occur, the movable part (the movable part of the steering wheel is pulled at the timing when the movable part of the handle is pulled by the user operation and when returning to the original natural position after the pulling). Alternatively, a hand of the user pulling the movable portion) is detected by the sensor, and the detection output is turned on. For this reason, if the output delay of the mangaichi sensor occurs and the door lock actuator is unlocked while the movable part is being pulled, for example, even if the automatic unlocking operation is disabled at that time, When the user stops pulling the movable portion and returns, the unlocking intention is detected again and the unlocking operation is executed again. Therefore, the possibility that the user needs to perform the operation of pulling the movable portion again thereafter is significantly reduced.
In addition, since a radio wave sensor is used, the movable part (or a user's hand pulling the movable part) can be detected relatively reliably without being affected by dirt, foreign matter, raindrops, or the like. It is possible to detect the user's unlocking intention.
Furthermore, since it is a simple configuration that does not require any detection means or switches besides or in the vicinity of the steering wheel other than the radio wave type sensor, the cost, the installation space, and the degree of freedom in vehicle design are low. This is advantageous.
[0010]
In a preferred aspect of the detection device of the present application, the radio wave sensor turns on a detection output even when a user's hand approaches the outside of the movable portion at a natural position.
According to such an embodiment, the user's intention is detected even at an early timing when the user's hand approaches the outside of the movable part to operate the steering wheel.
Note that the radio wave type sensor may be installed, for example, so as to transmit an output wave from the inside to the outside of the movable portion. In this case, a radio wave of a frequency band partially transmitted through the movable portion may be used. When used as an output wave, it is possible to reliably detect the approach of the user's hand to the outside of the movable section by the transmitted radio wave.
Further, it is preferable that the radio wave type sensor is attached to a portion inside the handle and fixedly provided to the opening / closing portion (that is, attached to a portion inside the handle that is not a movable portion). . This simplifies wiring to the sensor, which is advantageous in terms of productivity, cost, installation space, and design flexibility.
[0011]
Further, as the radio wave type sensor, the applicant has developed as a small-sized, simple, and easily mountable to a vehicle or the like, with a low possibility of erroneous detection, and has been developed by the applicant of the present invention. The following sensors proposed by 349415 can be used.
That is, a detection wave transmitting unit and a reflected wave receiving unit of the impulse radar, and an amplitude level of a signal component within a frequency range corresponding to a speed range in which a human hand operates, of a signal received by the reflected wave receiving unit. However, if it is within a predetermined range corresponding to the physical properties of the flap and the hand of a human hand, it is possible to use a device having a determination circuit unit for turning on the detection output. Here, the “physical property” is a property that affects the reflection characteristics of radio waves, and specifically is mainly a dielectric constant. Further, the “determination circuit unit” includes, for example, a filter (for example, a band-pass filter) that outputs only a signal component within the frequency range among the signals received by the reflected wave receiving unit, and an output of the filter. A comparator that compares the amplitude level with a threshold value corresponding to the boundary of the predetermined range, and turns on a detection output when the amplitude level is on the predetermined range side with respect to the threshold value. It can be realized with a simple configuration.
[0012]
Next, the lock control device of the present application is provided in the above-described detection device and an object having the opening / closing unit, and when a detection output of the detection device is turned on, a predetermined request signal to the portable device carried by the user is wirelessly transmitted. Transmitting, receiving an answer signal from the portable device in response to the request signal, and confirming that the received answer signal is appropriate, and then performing unlock control for unlocking the locked opening / closing unit. And a main unit to execute. That is, the detection device of the present application is used as a sensor for generating a trigger for the automatic unlocking function (for detecting a user's intention to unlock).
[0013]
Here, examples of the "thing having an opening / closing part" include a vehicle and a building. The “vehicle” may be a vehicle, a ship, an airplane, or the like. In addition, it goes without saying that the “building” includes offices, stores, warehouses, storerooms, etc. in addition to houses (condominiums, detached houses, etc.).
With this lock control device, it is possible to detect the user's intention to unlock at a plurality of timings as soon as possible. For example, the automatic unlocking function in the above-described keyless entry device can be made as responsive as possible to the movement of the user. , And can be operated reliably with a simple configuration, and the problems (a) and (b) described above can be solved.
[0014]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an example of an embodiment of the present invention will be described with reference to the drawings.
This embodiment is an example in which the present invention is applied to a control device of a passive entry system of a vehicle. As shown in FIG. 1, this system includes a portable device 10 carried by a user and a system device main body 20 provided on the vehicle side. The system device main body 20 means the entire equipment on the vehicle body side including the main unit 20a and the radio wave sensor 30.
The portable device 10 includes an antenna 11 and a receiver (receiving circuit) 12 for receiving a low-frequency (LF) start signal of, for example, about 100 to 150 kHz, and an answer signal described later at a high frequency (for example, a frequency in the UHF band). (Transmitter circuit) 13 and an antenna 14 for wirelessly transmitting an operation signal (locking operation signal or unlocking operation signal) and a controller (control circuit) including a microcomputer for controlling the entire portable device and performing necessary information processing. ) 15. Although not shown, the portable device 10 includes a portable device-side storage unit (for example, an EEPROM) for storing at least an authentication code (also referred to as an ID code or the like) and a built-in battery as a power supply. In this case, the portable device side storage means may be provided in the controller 15.
[0015]
Note that the start signal here is a signal that starts the microcomputer of the portable device 10 from the WAIT mode (low power consumption mode for suppressing power consumption, also referred to as a sleep state). In this case, the microcomputer of the portable device 10 is programmed such that when activated by the activation signal, the answer signal including the authentication code is transmitted on a high-frequency radio wave by radio, and in this sense, the activation signal is a request of the present invention. Signal.
Further, in this case, the power required for the portable device 10 (at least the power at the time of starting) may be covered by the power transmission from the main device 20a. In this case, since the transmission frequency from the main unit 20a to the portable unit 10 is a low frequency, the electric power can be transmitted relatively efficiently using this radio wave, and all the electric power necessary for the portable unit 10 is transmitted from the main unit. It is possible in principle to do so, so that the built-in battery of the portable device becomes unnecessary.
Note that the shape of the portable device 10 is not particularly limited, and may be, for example, a card shape or a mode incorporated in an ignition key.
[0016]
Further, on the surface of the portable device 10, for example, a lock switch and an unlock switch (not shown), which are push-button operation units, are provided, and a normal keyless entry system (one-way communication type). It may be configured to be capable of remote operation. That is, the portable device 10 has a function of starting up in response to the above-mentioned start-up signal and transmitting the answer signal a predetermined number of times, and is started up when the locking switch or the unlocking switch is operated, thereby setting the authentication code. It may have a function of wirelessly transmitting a lock operation signal including the lock operation signal or an unlock operation signal including the authentication code. Then, when these locking operation signals or unlocking operation signals are transmitted and received by the apparatus main body 20, the control function of the controller 21 of the apparatus main body 20 is used to perform collation confirmation and immediately open the vehicle door. Locking or unlocking operation may be performed.
[0017]
In addition, the portable device 10 of the present embodiment automatically returns to the WAIT mode when a necessary operation (for example, transmission of the answer signal) is completed, and thereafter continues the WAIT mode until a start signal is received. Is suppressed, but is not necessarily limited to such an embodiment. For example, the portable device 10 stands by as a standby mode in a normal state, shifts to an operation mode at predetermined timings, intermittently operates a receiving circuit, and performs a receiving operation intermittently. Then, a predetermined request signal wirelessly transmitted from the apparatus main body 20 in any of the intermittent receiving operations (a signal for simply requesting an answer signal instead of a start signal, and may be a high frequency signal as well as a low frequency signal). In response to this, an answer signal including the authentication code registered in the portable device-side storage means may be wirelessly transmitted a predetermined number of times in response to this.
[0018]
On the other hand, as shown in FIG. 1, the apparatus main body 20 includes a controller (control circuit) 21, a transmitter (transmitting circuit) 22, a transmitting antenna 23, a receiver (receiving circuit) 24, a receiving antenna 25, a door lock controller 26, The vehicle includes a door lock actuator 27, a relay 28, and a sensor 30. Note that the controller 21, the transmitter 22, the transmission antenna 23, the receiver 24, and the reception antenna 25 constitute a main unit 20a. The reference numeral 29 denotes a battery of the vehicle.
In this case, the transmitter 22 and the transmission antenna 23 are for transmitting the above-described low-frequency start signal, and the receiver 24 and the reception antenna 25 are for receiving the above-described high-frequency answer signal and the operation signal. Things.
The controller 21 includes a microcomputer that performs processing necessary for controlling the entire apparatus main body 20 and controlling the door lock actuator 27 via the door lock controller 26. In this case, an authentication code is not shown in the drawings. Built-in main unit side storage means (for example, EEPROM). Reference numerals 21a and 21b denote CPUs and timers constituting a microcomputer in the controller 21.
[0019]
The relay 28 is connected to the door lock actuator 27, connects the lock signal line L1 to the ground when the door is completely locked, and unlocks when the door is completely unlocked. The lock-side signal line L2 is connected to the ground.
Note that the controller 21, the transmitter 22, the receiver 24, and the like are provided in a control unit (ECU) arranged inside, for example, a door of a vehicle. Further, the transmitting antenna 23 and the receiving antenna 25 may be provided in the control unit. However, the transmitting antenna 23 and the receiving antenna 25 may be provided together with or separately from the transmitter 22 and the receiver 24 and at a different position from the control unit (for example, (A rearview mirror, a door mirror, a door or a door handle of a driver's seat or another seat, or around a trunk gate).
In this case, the output signal of the sensor 30 is input to the controller 21 via the sensor output line L3, and the power of the sensor 30 is supplied from the controller 21 via the power line L4.
[0020]
Next, the sensor 30 which is an example of a radio wave sensor will be described.
The basic configuration of the sensor 30 in this case has been developed by the applicant and has already been proposed by the above-mentioned application, and the outline thereof will be described below.
The sensor 30 detects a body (for example, a hand or a finger) of a vehicle user approaching a door handle (flap-type door handle) of the vehicle and generates a detection output that triggers an automatic unlocking operation of the door. This is a handle sensor and has a configuration shown in FIG. That is, it is roughly divided into a sensor main body 31, a transmitting antenna 32, and a receiving antenna 33. The sensor main body 31 includes a transmission clock generation circuit 34, an impulse shaping circuit 35, a reception clock generation circuit 36, a beat generation circuit 37, a sampling pulse shaping circuit 38, a sample and hold circuit 39, a determination circuit section 40, Having.
The transmission clock generation circuit 34, the impulse shaping circuit 35, and the transmission antenna 32 are elements corresponding to a detection wave transmitting unit of the impulse radar, and include a reception clock generation circuit 36, a beat generation circuit 37, a sampling pulse shaping circuit 38, The sample hold circuit 39 and the receiving antenna 33 are elements corresponding to a reflected wave receiving means of the impulse radar.
Further, the sensor main body 31 may be provided in the above-described control unit together with the controller 21 or the like, but may be stored in a door handle.
[0021]
Here, the transmission clock generation circuit 34 is a circuit that generates a reference wave (for example, 455 kHz) of the impulse radar, and is configured by, for example, an oscillation circuit that uses a quartz oscillator as an oscillation source. The reception clock generation circuit 36 is a circuit that generates a beat wave (for example, 1 kHz) of the impulse radar, and is configured separately from the transmission clock generation circuit 34 by, for example, a modified Colpitts type low current consumption oscillator.
[0022]
Next, the outline of the impulse shaping circuit 35, the beat generating circuit 37, the sampling pulse shaping circuit 38, and the sample and hold circuit 39 will be described.
The impulse shaping circuit 35 shapes the waveform generated by the transmission clock generation circuit 34 and inputs the waveform to the transmission antenna 32 as a predetermined rectangular wave (pulse). As a result, the transmission antenna 32 is periodically turned on and off, and a predetermined transmission wave (a frequency component limited by the bandwidth of the transmission antenna 32, including a harmonic) is emitted.
The beat generation circuit 37 is a circuit that generates a sampling pulse (having a fluctuation component corresponding to the beat wave) in which the waveform of the reference wave is changed by the beat wave. The sampling pulse shaping circuit 38 shapes the waveform generated by the beat generation circuit 37 and inputs the waveform to the sample and hold circuit 39. The sample-and-hold circuit 39 mixes the output of the sampling pulse shaping circuit 38 with the input from the receiving antenna 33 and outputs a predetermined low-frequency component (the component of the reflected wave from the detected object) in the input from the receiving antenna 33. Output). The technique of adding a fluctuation component corresponding to a beat wave to a sampling pulse is one method for efficiently receiving an appropriate reflected wave in an impulse radar.
[0023]
Next, as shown in FIG. 2B, the determination circuit unit 40 includes a low-frequency amplification circuit (AMP) 41, a cross-wire detection circuit 42, a band-pass filter (BPF) 43, a comparator 44, (I / F) 45.
Here, the low-frequency amplifier 41 is a circuit that amplifies the output of the sample-and-hold circuit 39 to a level that is easy to handle, and is not necessarily an essential element in principle. Further, the chopping wire detection circuit 42 is for performing a chopping wire detection on the output of the low-frequency amplification circuit 41 and removing an extra component (a high-frequency component other than a fluctuation component described later) in advance. As an output of the chopping wire detection circuit 42, a waveform mainly including a fluctuation component due to an object such as a hand approaching the antennas 32 and 33 is obtained. Here, the frequency of the fluctuation component increases / decreases according to the moving speed of an object such as a hand (the higher the moving speed, the higher the frequency naturally). The chopping wire detection circuit 42 is not necessarily an essential element in principle. In the subsequent band-pass filter 43, it is possible to perform processing including removal of the above-mentioned extra components. However, if the chopping line detection circuit 42 is used, extra components are removed in advance, so that signal processing can be performed efficiently.
In addition, the band-pass filter 43 outputs a frequency range (in this case, 1 Hz to several tens of Hz) corresponding to the speed range of the specific object (in this case, a human hand) to be detected in the output of the chopping wire detection circuit 42. This is a filter circuit that outputs only the signal components within the filter. The comparator 44 compares the amplitude level of the output of the band-pass filter 43 with a threshold value corresponding to the lower limit of a predetermined range corresponding to the physical properties (mainly dielectric constant) of the human hand in this case. On the other hand, when the amplitude level is within the predetermined range (that is, in this case, exceeding the threshold value), the output (detection output) is turned on. The interface 45 is a circuit that performs necessary signal form conversion and inputs the output of the comparator 44 to the controller 21 as a specific object detection output.
[0024]
According to the determination circuit unit 40, an attempt is made to detect that the output characteristic value (frequency and amplitude level) of the choke line detection circuit 42 exists in a predetermined determination area determined by the characteristics of the bandpass filter 43 and the comparator 44. The detection output is turned on as the specific object (human hand) approaches the antennas 32 and 33.
The amplitude level here is a parameter corresponding to the reception intensity (reception level) of the reception wave (reflection wave). If the difference in the distance from the antenna is ignored, the amplitude level mainly depends on the permittivity of the approaching object. Increase or decrease. For this reason, even if the frequency (that is, the approach speed of the foreign matter) of the foreign matter having a dielectric constant different from that of the specific object is substantially the same as that of the specific object, the waveform component does not fall below the threshold and does not enter the determination area and is not detected. In this case, for example, water, paper, plastic, or the like has a much lower dielectric constant than human hands. That is, even if, for example, a piece of paper or a dead leaf approaches the antennas 32, 33 at a speed similar to the movement of a human hand, erroneous detection that the detection output is turned on does not occur.
Further, the frequency (the frequency of the component due to the reflection of the object) in the output characteristic value of the chopping wire detection circuit 42 corresponds to the moving speed of the approaching object as described above. Therefore, even if the amplitude level (that is, the dielectric constant of the foreign substance) is substantially the same as that of the specific object, the waveform component due to the foreign substance having a different moving speed from the specific object enters the determination area outside the characteristic range of the bandpass filter 43. Not detected. In this case, for example, a falling object that moves faster than a human hand or an object that moves extremely slowly (including a stationary object) is an object (for example, metal) having a dielectric constant similar to that of a human hand, By the action of the band pass filter 43, it can be eliminated with high reliability. For example, even when the vehicle is parked with the antennas 32 and 33 approaching a metal pillar or the like, the metal pillar is not erroneously detected as a hand. In addition, even if raindrops having a high dielectric constant or the like fall, erroneous detection can be avoided with a high probability.
Therefore, according to the sensor 30 in this case, the detection output is reliably turned on when a human hand approaches, and in most cases, erroneous detection does not occur depending on the approach of other foreign substances or changes in the environment (at least, erroneous detection). A defect in which the detection continues repeatedly is avoided with high reliability.)
In addition, since it is a radio wave type, a much wider detection area (longer detection distance) can be set as compared with a capacitance type sensor. It is also possible to set a detection area in a specific area away from the sensor.
[0025]
Next, the attachment position of the sensor 30 to the flap-type door handle and the setting of the detection area will be described.
As shown in FIG. 3A, the flap-type door handle is attached to a door handle attaching portion 41 provided integrally with the door (opening / closing portion), and is swingably attached to the attaching portion 41. 3A, and a biasing means (for example, a coil spring) (not shown) for returning the flap 42 to a natural position (an initial position where no external force is applied) shown in FIG.
The flap 42 has no metal plating or the like hardly penetrating radio waves on its surface, and is made of a material having a relative dielectric constant (2 to 10) similar to that of human hands. Therefore, radio waves in the frequency band (100 kHz to 2 GHz) used by the sensor 30 are reflected at a rate of 20% to 50% on the surface of the flap 42, and the rest pass through the flap 42.
In this case, the sensor 30 has a structure in which the transmitting antenna 32 extends from the upper surface of the sensor main body 31, the receiving antenna 33 extends from the lower surface of the sensor main body 31, and the whole is covered with a cover 34, as shown in FIG. I have. The sensor 30 is arranged in a concave portion 41 a formed inside the flap 42 in the mounting portion 41, and is fixed to the mounting portion 41 (a portion fixedly provided to the opening / closing portion) by a screw 35. Have been.
[0026]
The detection area of the sensor 30 is set in the following area by adjusting the specifications of the antennas 32 and 33 and the characteristics of the determination circuit unit 40 described above. That is, it is set outside the flap 42 at the natural position and inside the flap 42 in the fully pulled state as shown in FIG. 3B. In this case, the distance between the flap 42 at the natural position and the sensor 30 is represented by reference symbol D0 as shown in FIG. 3A, and the distance between the flap 42 and the sensor 30 in the fully pulled state is as shown in FIG. 3B. When the distance between the sensor 30 and the detected object is larger than D3 (D3> D0) shown in FIG. 4B, D2 (D3 <D2 <D1) shown in FIG. The smaller area (the area of D ± ΔD shown in FIG. 5) is the detection area.
For this reason, in this sensor 30, when a hand or an object (for example, flap 42) having a dielectric constant equivalent thereto moves in the detection area (region of distance D3 to D2), as shown in FIG. Then, the reception level exceeds the threshold value (in this case, the threshold value determined by the characteristics of the determination circuit unit 40 described above), and the sensor output (that is, the detection output) is turned on as shown in FIG. More specifically, in this case, when the flap 42 moves into the detection area, the detection output is turned on by radio waves W1 and W2 transmitted from the transmission antenna 32, reflected on the inner surface of the flap 42 and received by the reception antenna 33. When the human hand T approaches the detection area outside the flap 42 at the natural position, the radio wave transmitted from the transmitting antenna 32, transmitted through the flap 42, reflected by the hand T, and received by the receiving antenna 33 The detection output is turned on by W3 and W4.
Therefore, according to the sensor 30, when the human hand T approaches the outside of the flap 42 at the natural position (distance D0), when the user pulls the flap 42 from the natural position and moves outward, When the user returns to the natural position from the position (for example, the distance D1) moved outward by the user, the detection output is turned on from off.
[0027]
Next, the function of the controller 21 and the operation of the present system will be described.
The controller 21 has a function of executing the following processing operation, for example. That is, basically, when the door of the vehicle is in a locked state (when the door lock actuator 27 is operating on the lock side), when the detection output of the sensor 30 is turned on, the transmitter 22 and the transmission antenna 23 The above-described activation signal is transmitted a predetermined number of times, and the receiver 24 is operated to execute a receiving operation. Then, when receiving the answer signal from the portable device 10 after transmitting the activation signal, it is determined whether or not the authentication code included in the answer signal corresponds to the authentication code registered in advance in the main unit side storage means. If the determination result is affirmative, it is determined that the collation has been confirmed, and the door lock actuator 27 is controlled to execute unlocking control for unlocking the locked vehicle door.
[0028]
FIG. 6 is an example of a flowchart for realizing the above-described control processing of the controller 21. In this case, the controller 21 starts the processing shown in FIG. 6 at, for example, a periodic timing.
When the process is started, first, in step S1, the potentials of the above-described lock-side signal line L1 and unlock-side signal line L2 are read, and it is determined whether or not the door is locked. If it is in the locked state, the process proceeds to the next step S2, and if it is not in the locked state, the processing of one sequence is terminated. When the processing of one sequence is completed, the processing is executed again from step S1 at the next timing.
Next, in step S2, it is determined whether or not a hand is detected (that is, whether or not the detection output of the sensor 30 is turned on). If it is detected, the process proceeds to step S4, where the detection is performed. If not, the processing of one sequence ends.
In step S4, the transmitter 22 is controlled to transmit the activation signal a predetermined number of times, and the operation of receiving the answer signal from the portable device 10 is executed.
[0029]
Next, in step S5, an answer signal in an appropriate format is received, the authentication code (ID code) included in the received signal is collated and confirmed, and it is determined whether the collation result is appropriate. If the collation result is appropriate, the process proceeds to step S6, and if not, the process of one sequence is terminated.
In step S6, the door lock actuator 27 is controlled to unlock the locked door. After step S6, the processing of one sequence ends.
In this case, if the unlocking operation in step S6 is not actually performed, the determination in step S1 becomes affirmative again at the next execution timing, and as a result, the processing in step S2 and subsequent steps is repeatedly performed. become. However, when the unlocking operation is not actually executed, the configuration may be such that step S2 and subsequent steps are immediately repeated without waiting for the next execution timing. That is, after step S6, there is provided a step of reading the potentials of the lock-side signal line L1 and the unlock-side signal line L2 to determine whether or not the unlocking operation has been completely performed. If is not executed, the process may return to step S2 and immediately repeat the process from step S2.
[0030]
With the processing described above and the configuration of the sensor 30 and the like described above, the operation shown in FIG. 7 is realized as the unlocking operation of the passive entry system.
That is, when the user holding the appropriate portable device 10 attempts to open the locked door and approaches his / her hand to the flap 42 of the door handle (step S21), the detection output of the sensor 30 is immediately turned on in a normal state. Therefore, the locked door is automatically unlocked at that time (steps S22, S31 to S34). Therefore, when the user performs the operation of pulling the flap 42, the automatic unlocking operation has already been completed, and the user can smoothly open the door without waiting for the unlocking, and immediately board the vehicle, for example. can do. When the user operates the flap 42 (when pulling and returning), the detection output of the sensor 30 is turned on as described above in a normal state, but as described above, the hand of the user approaches. Thus, when the automatic unlocking operation is performed early, the detection output is ignored and skipped as a result (steps S35 to S39).
Then, due to some factor (for example, an external radio wave from the surrounding environment that becomes noise for the sensor 30), the approach of the user's hand is not detected by the sensor 30 or the detection is delayed, and the user's hand approaches. If the automatic unlocking operation is not actually realized by performing the above operation, if the detection operation of the sensor 30 when the user pulls the flap 42 or thereafter returns the flap 42 is normal, , The detection output is turned on, and the locked door is automatically unlocked at that time (steps S23 to S28, S31 to S34).
Note that there are two modes of returning the user after pulling the flap 42 with the hand attached, and a mode of releasing the hand after pulling the hand. Since detection is possible in the same manner, if normal, the detection output is similarly turned on in any case.
In the worst case, when the user approaches the hand, pulls or returns the flap 42, the detection output is not normally output and the automatic unlocking operation is not performed. Then, the flap 42 can be operated again in the same manner as in the related art in order to activate the automatic unlocking function (step S29).
[0031]
According to the sensor 30 (detection device) of the present embodiment described above and the control device including the same, the following effects can be obtained.
As long as the sensor 30 does not fail, the user's hand approaches the outside of the flap 42 to operate the steering wheel, the flap 42 is pulled by the user operation, and the original natural position after the pull. At a total of three times when returning to step 3, the user's hand or flap 42 is detected by the sensor 30 and the detection output is turned on.
For this reason, in a normal state, the automatic unlocking operation is realized at the first early timing when the user's hand approaches the outside of the flap 42, and the comfort and convenience of the passive entry system are maximized. . Further, even if the automatic unlocking operation at the earlier timing is not realized, the next second timing (when the flap 42 is pulled by a user operation) or the third timing (flap 42). May return to the natural position), the user's intention to unlock may be detected and the automatic unlocking operation may be performed. Further, for example, when the output of the sensor 30 is delayed or the like, the door lock actuator 27 is unlocked while the flap 42 is being pulled, for example, at that time (based on the detection at the first or second timing described above). At the time of the unlocking operation), even if the automatic unlocking operation is disabled, when the user stops pulling the flap and the flap returns (the third timing described above), the unlocking intention is detected again. The unlocking operation is executed again.
In addition, since the radio wave type sensor is used, the flap 42 and the hand of the user are detected relatively reliably without being affected by dirt, foreign matter, raindrops, etc., and the user's intention to unlock is surely detected. It is possible to detect.
Therefore, after the user operates the flap 42, the possibility of operating the flap 42 again (or giving up the automatic unlocking operation and unlocking with a physical key) is greatly reduced, and the possibility is increased. The problems (a) and (b) described above can be solved.
[0032]
In addition, if an optical sensor is used, since the detection is performed based on the amount of light shielding, the following problem can be considered. Although various sensor mounting positions are conceivable, when the sensor is mounted on the finger insertion port and detection is performed based on the light blocking amount, the light blocking amount does not change much even if the user returns the flap while holding the flap. Conversely, when the hand is released from the flap and returned, the amount of light blocking tends to decrease, so that no sensor output is output. In this case, an act of grasping the flap again to output the sensor occurs.
In addition, when a capacitance sensor is used, a change in capacitance caused by contact with the flap is detected and a sensor signal is output, but a capacitance increase of “contact = capacitance increased” is generated. If the sensor output is used as a trigger, even if the user holds the flap and returns the flap to its original position, the capacitance change is small. No sensor signal is output because of the decrease. For this reason, in this case as well, an act of re-grip the flap occurs to output the sensor.
[0033]
Further, the sensor 30 need only be mounted on the handle mounting portion 41 inside the flap 42, as shown more practically in, for example, FIGS. 8A and 8B, and wiring is easy. In addition, since there is no need to provide other detecting means and switches around the steering wheel in addition to the radio wave type sensor 30, there is no problem in terms of productivity, cost, installation space, and vehicle design. This is advantageous in terms of the degree of freedom.
By the way, in the case of the capacitance sensor, for example, as shown in FIG. 8C, it is necessary to embed the electrodes 51 and 52 in the flap 42, and further, the signals between the electrodes 51 and 52 and the sensor body 53 are required. It is necessary to route the wire from the flap 42 which is a movable portion to the handle mounting portion 41 which is a fixed portion. This is disadvantageous in terms of cost, manufacturing process, design flexibility, and the like.
Therefore, with the sensor 30 of this example and a control device using the same, it is possible to arrange the sensor 30 in a limited space without any problem, there is no problem in design, and special processing can be performed on the door handle. There is no need to do so, and as already mentioned, the user will need to re-grip the handle, and the user will feel much less discomfort.
[0034]
Note that the present invention is not limited to the above-described embodiment, and may have various aspects.
For example, in the above embodiment, the detection area of the radio wave sensor is set outside the flap of the handle at the natural position, but the determination is made in consideration of the operation speed of the detection target as in the case of the sensor 30 described above. If the sensor does not detect a stationary object, there is no problem even if the detection area is distributed inside the flap at the natural position. This is because, in the case of the sensor as described above, if the flap stops at the natural position, the detection output is turned off even in the detection area.
Further, the control device of the present invention may not have a function of a general keyless entry system (a system for remotely operating a door lock mechanism by operating a switch provided on a portable device).
The present invention can also be widely applied to devices other than a vehicle entry system, as long as the device controls locking of a door or a similar opening / closing unit based on wireless communication between a portable device and a main device.
[0035]
【The invention's effect】
According to the present invention, as described above, the user's intention to open the opening / closing unit provided with the handle is detected as early as possible, and at a plurality of times for one operation of the user, It is possible to provide a detection device having a simple configuration capable of detecting the signal as quickly and reliably as possible, and a lock control device using the detection device.
[Brief description of the drawings]
FIG. 1 is a diagram showing a configuration of a lock control device for a vehicle door.
FIG. 2 is a diagram showing a main configuration of a sensor.
FIG. 3 is a diagram showing a structure, a mounting configuration, and the like of a sensor.
FIG. 4 is a diagram illustrating the operation of a handle and a sensor.
FIG. 5 is a diagram illustrating a detection area of a sensor.
FIG. 6 is a flowchart showing a control process of the main unit.
FIG. 7 is a flowchart showing a flow of an automatic unlocking operation.
FIG. 8 is a diagram showing a more practical mounting example and a comparative example of the sensor.
[Explanation of symbols]
42 flap (movable part of handle)
10 Portable device
20a Main unit
30 Electric wave type sensor

Claims (6)

A detection device for detecting a user's intention to open an opening / closing unit provided with a handle having a movable unit that operates outward by a user's pull operation,
Radio waves for turning on the detection output when the movable portion is pulled outward by the user from the natural position and moves outward, and when the movable portion returns to the natural position from the position where the movable portion is outwardly moved by the user. A detection device comprising a sensor of the type. The detection device according to claim 1, wherein the radio wave sensor turns on a detection output even when a user's hand approaches the outside of the movable portion in a natural position. The radio wave sensor is configured to transmit an output wave from the inside to the outside of the movable portion, and uses a radio wave of a frequency band partially transmitted through the movable portion as an output wave, The detecting device according to claim 2, wherein a hand of a user approaching the outside of the movable unit is detected by a transmitted radio wave. The detection device according to any one of claims 1 to 3, wherein the radio wave sensor is attached to a portion inside the handle and fixed to the opening / closing portion. The radio wave type sensor,
Detection wave transmitting means and reflected wave receiving means of the impulse radar,
Among the signals received by the reflected wave receiving means, the amplitude level of the signal component within the frequency range corresponding to the speed range in which the human hand operates is within the predetermined range corresponding to the physical properties of the flap and the human hand. The detection device according to any one of claims 1 to 4, further comprising: a determination circuit unit for turning on the detection output. A detection device according to any one of claims 1 to 5,
When the detection output of the detection device is turned on, the predetermined request signal for the portable device carried by the user is wirelessly transmitted, and an answer signal from the portable device for the request signal is received. And a main unit that executes unlock control for unlocking the locked opening / closing unit after confirming that the received answer signal is appropriate.

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