JP2015113006A - Rollover determination device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rollover determination device capable of preventing erroneous determination and determining that a rollover is occurring before a response request time even if a vehicle height is relatively low.SOLUTION: A rollover determination device comprises: first determination means for determining whether or not a rollover is occurring in a vehicle on the basis of whether or not a roll angular velocity and a lateral acceleration are included in a first determination area; sign determination means for determining whether or not there is a sign that the rollover might occur in the vehicle on the basis of the roll angular velocity when the first determination means determined that the rollover had not occurred in the vehicle; and second determination means for determining whether or not the rollover is occurring in the vehicle on the basis of whether or not the roll angular velocity and the lateral acceleration are included in a second determination area where sensitivity in determining that the rollover is occurring in the vehicle is set to be sensitive when the sign determination means determined that there was the sign that the rollover could occur in the vehicle.

Description

  The present invention relates to a rollover determination device that determines rollover (rollover) of a vehicle.

  As a form of rollover of a vehicle, a sandbox tripover as shown in FIG. 1 is known. Referring to FIG. 1, in a sandbox trip-over, for example, while a vehicle is running in a corner, the sandbox bulges outside the corner by lateral acceleration (centrifugal force), and the tire outside the corner has a higher coefficient of friction than a road surface such as asphalt. The vehicle hits and rolls over.

  Conventionally, as a technique for determining a rollover form in which a roll angle changes rapidly such as a sandbox tripover, a technique using a two-dimensional map of a vehicle's lateral acceleration and roll rate (roll angular velocity) is known (for example, Patent Document 1).

JP 2005-022553 A

  By the way, in response to a request for improving safety, a rollover determination device that is often mounted on a vehicle with a high vehicle height (for example, a commercial vehicle or an SUV (Sport Utility Vehicle)) is usually used. , Sedan, etc.).

  However, in a vehicle with a low vehicle height, there is a risk of inconvenience when performing rollover determination using a two-dimensional map of the lateral acceleration and the roll angular velocity of the vehicle as in Patent Document 1.

  That is, in order to reliably protect the occupant during rollover, a space in which the curtain shield airbag is interposed between the occupant head and the side window when the occupant head approaches the side window according to the roll of the vehicle. It is necessary to perform rollover determination while the vehicle is present (hereinafter, the time until the space for interposing the curtain shield airbag between the occupant's head and the side window is called “response request time”) . However, vehicles with low vehicle height tend to shorten the response request time because the space between the side window and the occupant's head is narrow due to the influence of design, size, etc. May be difficult. In addition, a vehicle with a low vehicle height has a low center of gravity and is difficult to roll over.For example, the lateral acceleration when a sandbox trip over occurs becomes very large, so the movement speed of the occupant head tends to increase. In some cases, it is difficult to make a rollover determination by the response request time. On the other hand, if the determination condition is relaxed so that the rollover determination can be made before the response request time, there is a possibility that the vehicle is erroneously determined that the rollover has occurred even if the behavior does not lead to the rollover.

  Therefore, in view of the above problems, when performing rollover determination due to sandbox tripover based on a two-dimensional map of the roll angular velocity and lateral acceleration of the vehicle, erroneous determination is made even for a vehicle having a relatively low vehicle height. An object of the present invention is to provide a rollover determination device that can determine that a rollover has occurred before the response request time while preventing the occurrence of a rollover.

In order to achieve the above object, in one embodiment, a rollover determination device includes:
Lateral acceleration detecting means for detecting the lateral acceleration of the vehicle;
Roll angular velocity detection means for detecting the roll angular velocity of the vehicle;
Roll angular acceleration detection means for detecting the roll angular acceleration of the vehicle;
Whether the first determination area includes the roll angular velocity detected by the roll angular velocity detector and the lateral acceleration detected by the lateral acceleration detector on the two-dimensional map using the vehicle's roll angular velocity and lateral acceleration as parameters. First determination means for determining whether or not a rollover has occurred in the vehicle depending on whether or not,
Whether the vehicle has a sign of rollover based on the roll angular acceleration detected by the roll angular acceleration detection means when the first determination means determines that no rollover has occurred in the vehicle A sign determination means for determining whether or not,
When it is determined by the sign determination means that there is a sign that the vehicle will roll over, the roll angular velocity detected by the roll angular speed detection means and the lateral acceleration detection means are detected on the two-dimensional map. Depending on whether or not the lateral acceleration is included in the second determination area that is set so that the sensitivity at which it is determined that a rollover has occurred in the vehicle is more sensitive than the first determination area, the vehicle has a rollover. Second determining means for determining whether or not it has occurred.

In another embodiment, the rollover determination device
Lateral acceleration detecting means for detecting the lateral acceleration of the vehicle;
Roll angular velocity detection means for detecting the roll angular velocity of the vehicle;
Roll angular acceleration detection means for detecting the roll angular acceleration of the vehicle;
Based on the roll angular acceleration detected by the roll angular acceleration detection means, a sign determination means for determining whether or not there is a sign of occurrence of rollover in the vehicle;
The roll angular velocity detected by the roll angular velocity detection means on the two-dimensional map using the roll angular velocity and lateral acceleration of the vehicle as parameters when it is determined by the sign determination means that there is no sign that the vehicle will roll over. And first determination means for determining whether or not a rollover has occurred in the vehicle based on whether or not the lateral acceleration detected by the lateral acceleration detection means is included in the first determination area;
When it is determined by the sign determination means that there is a sign that the vehicle will roll over, the roll angular velocity detected by the roll angular speed detection means and the lateral acceleration detection means are detected on the two-dimensional map. Depending on whether or not the lateral acceleration is included in the second determination area set so that the sensitivity at which it is determined that the rollover has occurred in the vehicle is more sensitive than in the first determination area, the vehicle rolls over. And a second determination means for determining whether or not the above has occurred.

  According to the present embodiment, when a rollover determination due to a sandbox tripover is performed based on a two-dimensional map of the roll angular velocity and lateral acceleration of the vehicle, an erroneous determination is made even for a vehicle having a relatively low vehicle height. It is possible to provide a rollover determination device that can determine that a rollover has occurred by the response request time while preventing the occurrence of the problem.

It is a figure explaining sandbox trip over. It is a block diagram which shows an example of a structure of a rollover determination apparatus. It is a flowchart which shows an example of the rollover determination operation | movement by a rollover determination apparatus (passenger protection ECU). It is a figure which shows an example of the rollover determination map (RAR-Gy determination map) which uses a roll angular velocity and a lateral acceleration as a parameter. It is a figure which shows an example of the roll over sign determination map (RAA-Gy determination map) which uses a roll angular acceleration and a lateral acceleration as parameters. It is a figure which shows an example of the RAR-Gy condition relaxation determination map which eased the determination conditions in the RAR-Gy determination map of FIG.

  Hereinafter, embodiments for carrying out the invention will be described with reference to the drawings.

  FIG. 2 is a block diagram illustrating an example of the configuration of the rollover determination device 1 according to the present embodiment. The rollover determination device 1 is mounted on a vehicle and determines whether or not a rollover has occurred in the vehicle, in particular, whether or not a rollover has occurred due to a sandbox tripover. In addition, when the rollover determination device 1 determines that a rollover has occurred in the vehicle, the rollover determination device 1 outputs an operation signal to an occupant protection device 40 to be described later, and operates the occupant protection device 40 to occupy the vehicle. Protect.

  The rollover determination device 1 includes a lateral acceleration sensor 10, a roll rate sensor 20, an occupant protection ECU 30, an occupant protection device 40, and the like.

  The lateral acceleration sensor (Gy sensor) 10 is a lateral acceleration detection unit that detects a lateral acceleration (a lateral acceleration) Gy of the vehicle. The lateral acceleration sensor 10 is communicably connected to the occupant protection ECU 30 via an in-vehicle LAN such as a CAN (Controller Area Network) or LIN (Local Interconnect Network), a direct line, etc., and a signal (voltage signal) corresponding to the detected lateral acceleration Gy. Etc.) to the occupant protection ECU 30. Note that any acceleration sensor capable of detecting the lateral acceleration of the vehicle may be applied to the lateral acceleration sensor 10.

  The roll rate sensor 20 is a roll angular velocity detection unit that detects a roll angular velocity (an angular velocity in the roll direction) RAR of the vehicle. The roll rate sensor 20 is communicably connected to the occupant protection ECU 30 via an in-vehicle LAN such as CAN or LIN, a direct line, or the like, and outputs a signal (voltage signal or the like) corresponding to the detected roll angular velocity RAR to the occupant protection ECU 30. The roll rate sensor 20 may be an arbitrary angular velocity sensor capable of detecting the roll angular velocity of the vehicle.

  In addition, as the lateral acceleration sensor 10 and the roll rate sensor 20, a sensor in which the lateral acceleration detection unit and the roll angular velocity detection unit are integrated in one housing may be applied.

  The occupant protection ECU 30 is an electronic control unit that controls the occupant protection device 40 of the vehicle. The occupant protection ECU 30 is configured as a microcomputer including a CPU, ROM, RAM, I / O, and the like, and may execute various control processes by executing a program stored in the ROM on the CPU. Specifically, the lateral acceleration Gy of the vehicle may be acquired from a signal received from the lateral acceleration sensor 10 based on characteristic information of the lateral acceleration sensor 10 stored in advance in a ROM or the like. Similarly, the roll angular velocity RAR may be acquired from a signal received from the roll rate sensor 20 based on the characteristic information of the roll rate sensor 20 stored in advance in a ROM or the like. Further, based on the acquired lateral acceleration Gy and roll angular velocity RAR of the vehicle, it is determined whether or not a rollover has occurred in the vehicle. Further, when it is determined that a rollover has occurred in the vehicle, an activation signal is output to the occupant protection device 40 according to the determination, and the occupant protection device 40 is activated. Details of the vehicle rollover determination by the occupant protection ECU 30 will be described later.

  The occupant protection device 40 is provided to protect the occupant when a rollover or the like occurs in the vehicle, and includes a curtain shield airbag 41, a seat belt pretensioner 42, and the like.

  The curtain shield airbag 41 is occupant protection means for protecting the occupant when a rollover occurs in the vehicle or when an obstacle collides with the side surface of the vehicle. Specifically, it is stored in a folded state inside the trim at the upper side of the vehicle interior, and an inflator (not shown) is activated in response to an activation signal from the occupant protection ECU 30 when a rollover occurs, etc. The airbag 41 is filled with gas, and expands downward. Thereby, the curtain shield airbag 41 is interposed between the head of the occupant and the side window, and the occupant's head can be protected.

  The seat belt pretensioner 42 is occupant protection means for appropriately restricting the amount of movement of the occupant by restraining the occupant when a collision or rollover occurs in the vehicle, thereby preventing the occupant from being released from the vehicle. Specifically, for example, it is provided attached to the seat belt retractor, and when a rollover occurs, a gas generator (not shown) is operated in response to an operation signal from the occupant protection ECU 30 to propel the generated gas. The seat belt is wound up early by force. Thereby, since a passenger | crew is restrained by a sheet | seat, a passenger | crew can be protected from discharge | release outside a vehicle or a collision with the structure in a vehicle interior.

  Next, a method for determining rollover by the rollover determination device 1 (occupant protection ECU 30), in particular, sandbox tripover will be specifically described.

  FIG. 3 is a flowchart showing an example of rollover determination processing by the rollover determination device 1 (occupant protection ECU 30). The rollover determination process is performed every predetermined time after the vehicle ignition is turned on (IG-ON) (specifically, after the completion of the primary process after IG-ON) and until the ignition is turned off (IG-OFF) (for example, , Every measurement cycle of the lateral acceleration sensor 10 and the roll rate sensor 20).

  First, in steps S101 to S103, preprocessing for performing rollover determination is executed.

  In step S101, the lateral acceleration Gy and roll angular velocity RAR of the vehicle are acquired from signals received from the lateral acceleration sensor 10 and the roll rate sensor 20.

  In step S102, the acquired lateral acceleration Gy and roll angular velocity RAR are filtered (for example, passed through a low-pass filter) in order to remove noise components.

  In step S103, the roll angular acceleration RAA of the vehicle is calculated based on the roll angular velocity RAR. Specifically, it may be calculated by differentiating the roll angular velocity RAR. In step S102, in order to avoid the phase delay due to the filtering process, for example, when tracking by the αβ filter is performed on the roll angular velocity RAR, the time differential estimation term in the αβ filter is used as the roll angular acceleration RAA of the vehicle. May be. Further, the roll angular acceleration RAA may be detected by the roll rate sensor 20. That is, the roll rate sensor 20 may output a signal corresponding to the roll angular acceleration RAA to the occupant protection ECU 30 after converting the signal corresponding to the roll angular velocity RAR into a signal corresponding to the roll angular acceleration RAA.

  Subsequently, in steps S104 to S108, specific rollover determination is performed based on the lateral acceleration Gy, roll angular velocity RAR, and roll angular acceleration RAA of the vehicle acquired in steps S101 to S103.

  In step S104, rollover determination using the first determination area A1 is performed on the two-dimensional map using the vehicle roll angular velocity RAR and the lateral acceleration Gy as parameters.

  Here, details of the rollover determination in step S104 will be described with reference to FIG.

  FIG. 4 is a diagram illustrating an example of a rollover determination map (RAR-Gy determination map) using the roll angular velocity RAR and the lateral acceleration Gy as parameters. The RAR-Gy determination map is a two-dimensional map in which the horizontal axis is the lateral acceleration Gy and the vertical axis is the roll angular velocity RAR, and a predetermined area for determining the occurrence of a preset rollover (in this example, the first 1 determination area A1) is provided.

  The first determination area A1 is derived, for example, based on a trajectory on a two-dimensional map when the vehicle has reached a rollover and when the vehicle has not reached a rollover, which is derived by computer simulation or an experiment using an actual vehicle. May be determined in advance.

  As an example, in FIG. 4, the trajectory when rollover is caused by a sandbox tripover is indicated by a solid line, and the trajectory when the user hits a sandbox but does not reach rollover (a limit case that does not lead to rollover) is indicated by a dotted line. . Note that the roll angular velocity RAR and the lateral acceleration Gy of the vehicle move on the locus in the direction of the arrow as time elapses. When comparing the two loci, the roll angular velocity RAR increases in accordance with the increase in the lateral acceleration Gy regardless of whether the rollover is reached or not. However, when the rollover is reached, the lateral acceleration Gy increases further than when the rollover is not reached, and the roll angular velocity RAR also increases accordingly. And even after the lateral acceleration Gy exceeds the peak, the roll angular velocity RAR increases, and the rollover is reached. On the other hand, when the rollover is not reached, after the lateral acceleration Gy exceeds the peak, the roll angular velocity starts to decrease and the rollover is avoided.

  Therefore, as shown in FIG. 4, it is preferable to set the first determination area A1 on the side away from the origin by the boundary line L1 so as not to include the locus when the rollover has not been reached. Thereby, when the point represented by the roll angular velocity RAR and the lateral acceleration Gy of the vehicle is included in the first determination area A1, it can be determined that a rollover has occurred in the vehicle. Specifically, when the point represented by the roll angular velocity RAR and the lateral acceleration Gy of the vehicle crosses the boundary line L1 from the origin side of the map (a time corresponding to the determination point JT1), the vehicle rolls over. Can be determined.

  Returning to FIG. 3, in step S <b> 104, it is determined based on the RAR-Gy determination map whether or not a rollover has occurred in the vehicle. If it is determined that rollover has occurred in the vehicle, the process proceeds to step S105, the establishment of rollover determination is confirmed, and the current process is terminated.

  On the other hand, if it is determined that no rollover has occurred in the vehicle, the process proceeds to step S106, but the rollover determination failure is not established, and the processes of steps S106 to S107 described later are subsequently executed.

  Here, when the rollover determination is performed using the RAR-Gy determination map shown in FIG. 4, the response request time (the time until the space for interposing the curtain shield airbag 41 between the occupant's head and the side window is insufficient. ) May not be in time. In particular, as compared with a vehicle having a high vehicle height, in a vehicle having a relatively low vehicle height, as described above, the response request time tends to be small. Therefore, the rollover determination by the RAR-Gy determination map shown in FIG. Then, there is a high possibility that the response request time will not be met. That is, referring to FIG. 4, the rollover determination by the RAR-Gy determination map using the first determination area A1 is performed after the timing corresponding to the determination point JT1, but the point RT1 corresponding to the response request time is Since it does not reach the first determination area A1, the response request time cannot be satisfied. Further, since the point RT1 corresponding to the response request time can be recognized as being on both the trajectory when the rollover is reached and when the rollover is not reached, in the RAR-Gy determination map shown in FIG. It is not possible to determine whether a rollover has occurred when the request time has elapsed.

  Therefore, in steps S106 to S107, it is determined whether or not there is a sign of occurrence of rollover based on the roll angular acceleration RAA. If there is a sign of occurrence of rollover, the conditions are relaxed again (rollover). The rollover determination is performed based on the RAR-Gy determination map (sensitivity determined to be).

  In step S106, rollover sign determination is performed on a two-dimensional map using the vehicle roll angular acceleration RAA and the lateral acceleration Gy as parameters.

  Here, the details of the rollover sign determination in step S106 will be described with reference to FIG.

  FIG. 5 is a diagram illustrating an example of a rollover sign determination map (RAA-Gy determination map) using the roll angular acceleration RAA and the lateral acceleration Gy as parameters. The RAA-Gy determination map is a two-dimensional map in which the horizontal axis is the lateral acceleration Gy and the vertical axis is the roll angular acceleration RAA, and a predictor determination area Aa for determining a preset sign of occurrence of rollover is provided. .

  The sign determination area Aa is derived, for example, based on a trajectory on a two-dimensional map when the vehicle has reached rollover and when the vehicle has not reached rollover, which is derived by computer simulation or an experiment using an actual vehicle. It may be determined in advance.

  As an example, in FIG. 5, the locus when rolled over due to a sandbox trip is indicated by a solid line, and the locus when the vehicle hits a sandbox but does not reach a rollover (a limit case that does not lead to rollover) is indicated by a dotted line. . It is assumed that the roll angular acceleration RAA and the lateral acceleration Gy of the vehicle move in the direction of the arrow on the trajectory as time elapses. The trajectory when the rollover is reached corresponds to the trajectory when the rollover is reached in FIG. 4, and the trajectory when the rollover is not reached is the trajectory when the rollover is not reached in FIG. Corresponding to When comparing the two loci, the roll angular acceleration RAA rapidly increases and the roll angular acceleration RAA reaches a peak in accordance with the increase in the lateral acceleration Gy, regardless of whether the rollover is reached or not. Thereafter, the roll angular acceleration RAA starts to decrease, the roll angular acceleration RAA decreases according to the increase of the lateral acceleration Gy, and after the lateral acceleration Gy reaches the peak, the roll angle acceleration RAA decreases according to the decrease of the lateral acceleration Gy. The acceleration RAA continues to decrease. However, when the roll over is reached, the value of the lateral acceleration Gy when the roll angular acceleration RAA reaches the peak is larger than when the roll over is not reached, and the maximum value of the roll angular acceleration RAA is also increased. It is getting bigger.

  Therefore, as shown in FIG. 5, the sign determination area Aa may be set on the side away from the origin by the boundary line La so as not to include the locus when the rollover has not been reached. Thereby, when the point represented by the roll angular acceleration RAA and the lateral acceleration Gy of the vehicle is included in the sign determination area Aa, it can be determined that the vehicle has a sign of occurrence of rollover. Specifically, when the point represented by the roll angular acceleration RAA and the lateral acceleration Gy of the vehicle crosses the boundary line La from the origin side of the map (a time corresponding to the determination point JTa), a sign of occurrence of rollover in the vehicle. It can be determined that there is. The point RTa corresponding to the response request time is included in the sign determination area Aa, and it can be seen that the sign of occurrence of rollover can be detected by the response request time based on the roll angular acceleration RAA.

  Returning to FIG. 3, in step S <b> 106, it is determined based on the RAA-Gy determination map whether the vehicle has a sign of occurrence of rollover. If it is determined that the vehicle has a sign of occurrence of rollover, the process proceeds to step S107. When it is determined that there is no sign of occurrence of rollover in the vehicle, the process proceeds to step S108, the rollover determination is not established, and the current process is terminated.

  In step S107, the determination condition is eased again, and rollover determination is performed using the RAR-Gy determination map. That is, the first determination area A1 for determining whether or not a rollover has occurred in the vehicle is changed to the second determination area A2 having a sensitive rollover determination sensitivity, and the roll according to the RAR-Gy determination map is performed. Perform over determination.

  Here, details of the rollover determination in step S107 will be described with reference to FIG.

  FIG. 6 is a diagram illustrating an example of the RAR-Gy condition relaxation determination map in which the determination conditions in the RAR-Gy determination map of FIG. 4 are relaxed. As in FIG. 4, the locus when rolled over due to a sandbox trip is indicated by a solid line, and the locus when the vehicle hits a sandbox or the like but does not reach a rollover (a limit case where the rollover does not occur) is indicated by a dotted line.

  Referring to FIG. 6, with respect to the boundary line L1 of the first determination area A1, the boundary line L2 of the second determination area A2 projects to the origin side of the map, and the second determination area A2 is more than the first determination area A1. Also, the area is enlarged on the origin side of the map. The second determination area A2 is set so as to include a point RT1 corresponding to the response request time. Therefore, it can be determined that a rollover has occurred in the vehicle by the response request time by the RAR-Gy determination map (RAR-Gy condition relaxation determination map) using the second determination area A2.

  Returning to FIG. 3, in step S107, based on the RAA-Gy condition relaxation determination map, it is determined whether or not a rollover has occurred in the vehicle. If it is determined that rollover has occurred in the vehicle, the process proceeds to step S105, the establishment of rollover determination is confirmed, and the current process is terminated. If it is determined that no rollover has occurred in the vehicle, the process proceeds to step S108, where the rollover determination is not established, and the current process is terminated.

  When the rollover determination is established by the rollover determination process described above, the occupant protection ECU 30 outputs an operation signal to the occupant protection device 40 (curtain shield airbag 41, seat belt pretensioner 42, etc.). Thereby, when the roll over has generate | occur | produced in the vehicle, the passenger | crew protection apparatus 40 can be operated and the passenger | crew of a vehicle can be protected.

  As described above, the rollover determination device 1 (occupant protection ECU 30) according to the present embodiment determines whether or not the acquired roll angular velocity RAR and lateral acceleration Gy are included in the first determination area A1 based on the RAR-Gy determination map. To determine whether a rollover has occurred in the vehicle. Further, when it is determined by the determination that the rollover has not occurred in the vehicle, it is determined whether or not there is a sign that the vehicle will roll over based on the acquired roll angular acceleration RAA. Specifically, based on the RAA-Gy sign determination map, the vehicle rolls over depending on whether or not the acquired roll angular acceleration RAA and lateral acceleration Gy are included in the sign determination area Aa set on the side away from the origin. It is determined whether or not there is a sign of occurrence. Furthermore, if it is determined that the vehicle has a sign that rollover will occur, whether the acquired roll angular velocity RAR and lateral acceleration Gy are included in the second determination area A2 based on the RAR-Gy condition relaxation determination map. Whether or not a rollover has occurred in the vehicle is determined based on whether or not the vehicle is not. Specifically, the second determination area A2 is set so that the sensitivity at which it is determined that a rollover has occurred in the vehicle is more sensitive than the first determination area A1. That is, the second determination area A2 is set by enlarging the area on the origin side with respect to the first determination area A1 set on the side away from the origin on the determination map. Thereby, it can be determined that rollover has occurred in the vehicle at an early stage. In addition, by appropriately setting the second determination area A2, it is possible to make a rollover determination by the response request time of the curtain shield airbag 41, so that the curtain shield airbag 41 can be appropriately operated to It can be surely protected. In particular, in the case of a vehicle having a relatively low vehicle height, the response request time tends to be earlier, so by applying the rollover determination device 1 according to the present embodiment, the curtain shield airbag 41 is appropriately operated, Vehicle occupants can be reliably protected.

  In addition, the RAR-Gy determination map is used to determine a sign of occurrence of rollover on the basis of the roll angular acceleration RAA that causes a difference at an early stage between when the vehicle reaches rollover and when the vehicle does not rollover. Since the conditions are relaxed, erroneous determination can be prevented.

  In this embodiment, when it is determined that no rollover has occurred in the vehicle based on the RAR-Gy determination map, the rollover precursor determination based on the RAA-Gy determination map is performed. Rollover predictor determination may be performed.

  That is, rollover sign determination based on the RAA-Gy determination map is performed, and when it is determined that there is a sign that rollover will occur, based on the RAR-Gy condition relaxation determination map using the second determination area A2, A rollover determination may be performed. When it is determined that there is no sign that rollover will occur, rollover determination may be performed based on the RAR-Gy determination map using the first determination area A1. Thereby, it is possible to determine that rollover has occurred at an early stage while preventing erroneous determination, as in the above-described embodiment.

  As mentioned above, although the form for implementing this invention was explained in full detail, this invention is not limited to this specific embodiment, In the range of the summary of this invention described in the claim, various Can be modified or changed.

1 Rollover judging device 10 Lateral acceleration sensor (lateral acceleration detecting means)
20 Roll rate sensor (roll angular velocity detection means)
30 Occupant protection ECU (roll angular acceleration detection means, first determination means, sign determination means, second determination means)
40 Occupant Protection Device 41 Curtain Shield Airbag 42 Seat Belt Pretensioner A1 First Judgment Area A2 Second Judgment Area Aa Predictive Judgment Area

Claims (4)

Lateral acceleration detecting means for detecting the lateral acceleration of the vehicle;
Roll angular velocity detection means for detecting the roll angular velocity of the vehicle;
Roll angular acceleration detection means for detecting the roll angular acceleration of the vehicle;
Whether the first determination area includes the roll angular velocity detected by the roll angular velocity detector and the lateral acceleration detected by the lateral acceleration detector on the two-dimensional map using the vehicle's roll angular velocity and lateral acceleration as parameters. First determination means for determining whether or not a rollover has occurred in the vehicle depending on whether or not,
Whether the vehicle has a sign of rollover based on the roll angular acceleration detected by the roll angular acceleration detection means when the first determination means determines that no rollover has occurred in the vehicle A sign determination means for determining whether or not,
When it is determined by the sign determination means that there is a sign that the vehicle will roll over, the roll angular velocity detected by the roll angular speed detection means and the lateral acceleration detection means are detected on the two-dimensional map. Depending on whether or not the lateral acceleration is included in the second determination area that is set so that the sensitivity at which it is determined that a rollover has occurred in the vehicle is more sensitive than the first determination area, the vehicle has a rollover. Second determining means for determining whether or not it has occurred,
Rollover judging device. Lateral acceleration detecting means for detecting the lateral acceleration of the vehicle;
Roll angular velocity detection means for detecting the roll angular velocity of the vehicle;
Roll angular acceleration detection means for detecting the roll angular acceleration of the vehicle;
Based on the roll angular acceleration detected by the roll angular acceleration detection means, a sign determination means for determining whether or not there is a sign of occurrence of rollover in the vehicle;
The roll angular velocity detected by the roll angular velocity detection means on the two-dimensional map using the roll angular velocity and lateral acceleration of the vehicle as parameters when it is determined by the sign determination means that there is no sign that the vehicle will roll over. And first determination means for determining whether or not a rollover has occurred in the vehicle based on whether or not the lateral acceleration detected by the lateral acceleration detection means is included in the first determination area;
When it is determined by the sign determination means that there is a sign that the vehicle will roll over, the roll angular velocity detected by the roll angular speed detection means and the lateral acceleration detection means are detected on the two-dimensional map. Depending on whether or not the lateral acceleration is included in the second determination area set so that the sensitivity at which it is determined that the rollover has occurred in the vehicle is more sensitive than in the first determination area, the vehicle rolls over. A second determination means for determining whether or not the
Rollover judging device. The first determination area is
Set to the side away from the origin,
The second determination area is
The first determination area is set to be widened toward the origin,
The rollover determination apparatus according to claim 1 or 2. The sign determination means includes
On the two-dimensional map using the roll angular acceleration and lateral acceleration of the vehicle as parameters, the roll angular acceleration detected by the roll angular acceleration detection means and the lateral acceleration detected by the lateral acceleration detection means are on the side away from the origin. It is determined whether or not there is a sign that the vehicle will roll over depending on whether or not it is included in the sign determination area set in
The rollover determination device according to any one of claims 1 to 3.

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