JP5593946B2 - Vehicle control device - Google Patents

Description

  The present invention relates to a vehicle control device.

  In recent vehicles, in order to improve the ease of driving when the vehicle is running, to reduce the burden of driving operations by the driver, and to improve the safety when the vehicle is running, control during driving of the vehicle is performed. Control devices that allow automatic operation have been developed.

  For example, in the inter-vehicle control device described in Patent Document 1, follow-up running control that maintains the inter-vehicle distance between the host vehicle and the preceding vehicle at a predetermined distance is possible. In the inter-vehicle distance control device, the target acceleration is corrected based on the relative acceleration between the host vehicle and the preceding vehicle, and the inter-vehicle control is executed based on the corrected target acceleration, so that the preceding vehicle decelerates strongly. However, the behavior change can be captured without delay, and deceleration control can be performed at an appropriate timing.

JP 2000-108719 A

  However, the inter-vehicle distance when the preceding vehicle decelerates when following traveling control is performed on the preceding vehicle changes not only due to the deceleration of the preceding vehicle but also due to other factors such as the traveling state of the host vehicle. . For this reason, when the following control is performed based on only the inter-vehicle distance from the preceding vehicle or the deceleration of the preceding vehicle, the inter-vehicle control may not be performed properly. The control had room for improvement.

  The present invention has been made in view of the above, and an object of the present invention is to provide a vehicle control device that can more appropriately perform the inter-vehicle distance control during follow-up traveling.

  In order to solve the above-described problems and achieve the object, the vehicle control device according to the present invention acquires travel information of a preceding vehicle that travels ahead in the travel direction of the host vehicle, and based on the acquired travel information. A vehicle control device that performs a follow-up running control that follows the preceding vehicle, wherein at the time of the follow-up running control, the start of the acceleration / deceleration control of the preceding vehicle is started from the start time of the acceleration / deceleration control of the preceding vehicle. As a sum of a detection delay time until the vehicle detects and a control response delay time from when the vehicle transmits an acceleration / deceleration control signal until the vehicle starts acceleration / deceleration control. An inter-vehicle time between the preceding vehicle and the host vehicle is set, and at least one of the detection delay time or the control response delay time according to at least one of an environment or a driving situation when the host vehicle travels Change Characterized in that it.

  In the vehicle control device, it is preferable that the environment when the host vehicle travels is a temperature around the host vehicle.

  In the vehicle control device, it is preferable that the traveling state is in the form of detection means used for acquiring the traveling information.

  In the vehicle control device, it is preferable that the traveling state is a driving force generation form during acceleration of the host vehicle.

  In the vehicle control device, it is preferable that the traveling state is a generation form of a braking force when the host vehicle is decelerated.

  The vehicle control device according to the present invention has an effect that the inter-vehicle distance control during follow-up traveling can be performed more appropriately.

FIG. 1 is a schematic view of a vehicle provided with a vehicle control apparatus according to an embodiment of the present invention. FIG. 2 is a main part configuration diagram of the vehicle control device shown in FIG. 1. FIG. 3 is an explanatory diagram of the follow-up running. FIG. 4 is an explanatory diagram showing acceleration and relative acceleration between the preceding vehicle and the host vehicle when the preceding vehicle is decelerated. FIG. 5 is an explanatory diagram when the own vehicle decelerates after the start of deceleration of the preceding vehicle. FIG. 6 is an explanatory diagram when the vehicle is decelerated at a small deceleration with respect to the deceleration described in FIG. FIG. 7 is an explanatory diagram when the initial speed is slower than the deceleration described in FIG. FIG. 8 is an explanatory diagram showing the relationship between the acceleration, relative acceleration, and relative speed between the host vehicle and the preceding vehicle during deceleration. FIG. 9 is an explanatory diagram of acceleration between the preceding vehicle and the host vehicle during deceleration during the follow-up running control. FIG. 10 is an explanatory diagram of the equivalent reaction time. FIG. 11 is an explanatory diagram of control at the time of occurrence of communication interruption.

  Hereinafter, an embodiment of a vehicle control device according to the present invention will be described in detail with reference to the drawings. In addition, this invention is not limited by this embodiment. In addition, constituent elements in the following embodiments include those that can be easily replaced by those skilled in the art or those that are substantially the same.

Embodiment
FIG. 1 is a schematic view of a vehicle provided with a vehicle control apparatus according to an embodiment of the present invention. A vehicle 1 including a vehicle control device 2 according to the embodiment is equipped with an engine 5 that is an internal combustion engine as a power source, and the power generated by the engine 5 passes through a drive device such as an automatic transmission (not shown). By being transmitted to 3, it is possible to travel. Further, the vehicle 1 is provided with a brake device (not shown) that is a braking means for braking the vehicle 1 that is running by braking the wheels 3, and controls the hydraulic pressure when the brake device is operated. A brake hydraulic control device 8 is provided. Further, the drive device is provided with a vehicle speed sensor 10 which is a vehicle speed detection means for detecting the vehicle speed by detecting the rotational speed when the power of the engine 5 is transmitted to the wheels 3.

  Further, the vehicle 1 communicates information such as traveling state information between the radar 12 which is a front situation detection means for detecting other vehicles traveling in front and obstacles positioned in the traveling direction, and the other vehicles. And a vehicle-to-vehicle communication device 15 which is a vehicle-to-vehicle communication means capable of performing the above. Among these, the radar 12 may be in any form as long as it can be mounted on the vehicle 1 such as a laser radar using a laser as a detection wave or a millimeter wave radar using a millimeter wave. The inter-vehicle communication device 15 includes various devices necessary for wireless communication, such as an antenna that transmits and receives electromagnetic waves, a signal transmission device, and a reception device.

  The engine 5, the brake hydraulic pressure control device 8, the vehicle speed sensor 10, the radar 12, and the inter-vehicle communication device 15 are mounted on the vehicle 1 and connected to an ECU (Electronic Control Unit) that controls each part of the vehicle 1. . As this ECU, a travel control ECU 20 that performs travel control of the vehicle 1, a communication follow-up travel control ECU 40 that performs communication follow-up travel control that is travel control that performs travel following the preceding vehicle while communicating with other vehicles, The vehicle has an autonomous follow-up running control ECU 60 that performs autonomous follow-up running control that is a run control that autonomously follows the preceding vehicle without communicating with other vehicles.

  FIG. 2 is a main part configuration diagram of the vehicle control device shown in FIG. 1. Among the components connected to the ECU, devices used for traveling the vehicle 1 such as the engine 5, the brake hydraulic pressure control device 8, and the vehicle speed sensor 10 are connected to the travel control ECU 20, and the travel control ECU 20 includes A brake sensor 9 is connected to detect an operation amount of a brake pedal (not shown) that is operated by the driver when the vehicle 1 is decelerated. The travel control ECU 20 performs travel control of the vehicle 1 by operating the engine 5, the brake hydraulic pressure control device 8, and the like based on detection results by detection means such as the vehicle speed sensor 10 and the brake sensor 9.

  The inter-vehicle communication device 15 used for communication with other vehicles is connected to the communication follow-up travel control ECU 40, and the communication follow-up travel control ECU 40 uses the inter-vehicle communication device 15 to communicate information on the travel state with other vehicles. The communication follow-up traveling control is performed by transmitting a control signal to the traveling control ECU 20 and performing the traveling control of the vehicle 1 while performing the communication. The radar 12 used as an inter-vehicle distance detecting means for detecting the inter-vehicle distance between the own vehicle and the preceding vehicle in the autonomous following traveling control by detecting other vehicles traveling in front of the autonomous following traveling control ECU 60. The autonomous follow-up travel control ECU 60 transmits a control signal to the travel control ECU 20 while detecting the inter-vehicle distance between the host vehicle and the preceding vehicle by the radar 12, and sets the inter-vehicle distance detected by the radar 12 as a target value. The autonomous tracking traveling control is performed by performing the traveling control to be maintained.

  The travel control ECU 20, the communication follow-up travel control ECU 40, and the autonomous follow-up travel control ECU 60 are connected to each other so that information and signals can be exchanged. The hardware configurations of the travel control ECU 20, the communication follow-up travel control ECU 40, and the autonomous follow-up travel control ECU 60 include a processing unit having a CPU (Central Processing Unit), a storage unit such as a RAM (Random Access Memory), and the like. Because of this configuration, the description is omitted.

  Among these ECUs, the travel control ECU 20 includes an engine control unit 21 that controls the operation of the engine 5, a brake control unit 22 that controls the braking force by controlling the brake hydraulic pressure control device 8, and the vehicle speed sensor 10. The communication speed of the vehicle speed acquisition unit 25 that acquires the vehicle speed from the detection result of the vehicle, the brake operation acquisition unit 26 that acquires the state of operation of the brake pedal from the detection result of the brake sensor 9, and the travel mode when the vehicle 1 is traveling A traveling mode switching unit 28 that switches between traveling control, autonomous following traveling control, and manual traveling control that is traveling control performed by a driver's driving operation without performing these following traveling controls, and detection results by the radar 12 Based on the deceleration of the preceding vehicle, and an inter-vehicle time detecting means 30 that is an inter-vehicle time detecting means for detecting an inter-vehicle time with the preceding vehicle The deceleration calculation unit 33 that calculates the deceleration of the host vehicle, the relative speed calculation unit 34 that calculates the relative speed with the preceding vehicle based on the detection result of the radar 12, and the relative speed used when performing the deceleration control. A deceleration relative speed calculation unit 35 to calculate, and an inter-vehicle time setting unit 38 that sets an inter-vehicle time with a preceding vehicle when performing follow-up traveling control according to an acquisition state of traveling information of the preceding vehicle. Yes.

  Further, the communication follow-up travel control ECU 40 has an inter-vehicle distance setting unit 41 that sets an inter-vehicle distance based on an inter-vehicle time that is set in advance for the communication follow-up travel control. The preceding vehicle traveling information acquisition unit 45 that acquires traveling information of the preceding vehicle by inter-vehicle communication performed by the device 15, the preceding vehicle maximum deceleration deriving unit 46 that derives the maximum deceleration when the preceding vehicle decelerates, and the inter-vehicle communication A communication interruption determination unit 51 that determines whether or not communication with the preceding vehicle performed by the device 15 is interrupted.

  In addition, the autonomous follow-up travel control ECU 60 uses the detection result of the radar 12 to obtain the front state acquisition unit 61 that obtains the front state of the vehicle 1 and the inter-vehicle distance during the autonomous follow-up travel control. An inter-vehicle distance setting unit 62 that sets an inter-vehicle distance based on a preset inter-vehicle time and a vehicle speed acquired by the vehicle speed acquisition unit 25; a preceding vehicle deceleration deriving unit 63 that derives a deceleration at the time of deceleration of the preceding vehicle; ,have.

  The vehicle control device 2 according to this embodiment is configured as described above, and the operation thereof will be described below. When the vehicle 1 is traveling normally, the driver operates the accelerator pedal (not shown) and the brake pedal, whereby the actuators such as the engine 5 and the brake hydraulic pressure control device 8 are operated, and the vehicle 1 is operated by the driver. Drive according to the operation. For example, when adjusting the power generated by the engine 5, the engine control unit 21 included in the travel control ECU 20 controls the engine 5, and when generating the braking force, the brake control unit 22 included in the travel control ECU 20. A braking force is generated by controlling the brake hydraulic pressure control device 8.

  Further, when the vehicle 1 travels, the travel state of the vehicle 1 and the driving operation of the driver are detected by sensors provided in each part of the vehicle 1 and are used for travel control of the vehicle 1. For example, the detection result detected by the vehicle speed sensor 10 is acquired by the vehicle speed acquisition unit 25 included in the travel control ECU 20 and used when the travel control is performed using the vehicle speed. Similarly, the detection result detected by the brake sensor 9 is acquired by the brake operation acquisition unit 26 included in the travel control ECU 20 as the operation amount of the brake operation performed by the driver, and the brake control unit 22 performs braking according to the acquired operation amount. The hydraulic control device 8 is controlled to generate a braking force.

  In addition, the vehicle 1 is configured to follow the other vehicle that travels ahead of the vehicle 1 as necessary based on the driver's intention, such as operating a follow-up operation switch (not shown). It is provided that can be performed. In other words, follow-up traveling control can be performed as traveling control that supports driving operations by the driver. In the follow-up running control, the communication follow-up running control and the autonomous follow-up running control are properly used according to the state of the vehicle 1 during running.

  FIG. 3 is an explanatory diagram of the follow-up running. First, autonomous tracking traveling control will be described. When autonomous tracking traveling control is performed, the front state of the vehicle 1 is detected by the radar 12, and the autonomous tracking traveling control ECU 60 has a front based on the detection result of the radar 12. The state acquisition unit 61 acquires the state in front of the vehicle 1. The front state acquisition unit 61 detects the presence or absence of a preceding vehicle 100 that is another vehicle traveling in front of the vehicle 1, and when the preceding vehicle 100 exists, the distance from the preceding vehicle 100 is determined by the radar 12. Obtained based on the detection result.

  Further, at the time of autonomous tracking traveling control, the inter-vehicle distance setting unit 62 sets the inter-vehicle distance according to the vehicle speed acquired by the vehicle speed acquisition unit 25 included in the traveling control ECU 20. When setting this inter-vehicle distance, the inter-vehicle distance setting unit 62 is used for the autonomous follow-up travel that is set in advance as a time with the preceding vehicle 100 suitable for autonomous follow-up running and stored in the storage unit. And the vehicle speed acquired by the vehicle speed acquisition unit 25 of the travel control ECU 20 is set.

  The autonomous tracking travel control ECU 60 adjusts the speed of the vehicle 1 so that the inter-vehicle distance with the preceding vehicle 100 acquired by the front state acquisition unit 61 is approximately the same as the inter-vehicle distance set by the inter-vehicle distance setting unit 62. Then, a signal is transmitted to the travel control ECU 20. Receiving this signal, the travel control ECU 20 adjusts the driving force and braking force by the engine control unit 21 and the brake control unit 22, thereby setting the inter-vehicle distance from the preceding vehicle 100 by the inter-vehicle distance setting unit 62. Maintain a similar distance. Thereby, the follow-up traveling following the preceding vehicle 100 is performed.

  Next, communication follow-up running control will be described. The communication follow-up running control is performed in the case of a communication vehicle that is a vehicle in which other vehicles traveling around can communicate travel information with each other. That is, when the preceding vehicle 100 is a communication vehicle, communication follow-up running control can be performed. When performing communication follow-up running control, vehicle-to-vehicle communication is performed with the preceding vehicle 100 via the vehicle-to-vehicle communication device 15, and travel information of the preceding vehicle 100 is acquired.

  The travel information of the preceding vehicle 100 is acquired by the communication follow-up travel control ECU 40 using the travel information transmitted from the preceding vehicle 100 by the inter-vehicle communication performed with the preceding vehicle 100 by the inter-vehicle communication device 15. Obtained by the travel information obtaining unit 45. The travel information includes information on the state of motion of the communication vehicle, information on the driving operation of the driver, and position information on the communication vehicle.

  When the traveling information of the preceding vehicle 100 is acquired, the preceding vehicle 100 is determined by the inter-vehicle distance setting unit 41 according to the vehicle speed acquired by the vehicle speed acquisition unit 25, the vehicle speed of the preceding vehicle 100, and the current driving operation of the driver of the preceding vehicle 100. Set the distance between the two cars. When setting the inter-vehicle distance at the time of communication follow-up control, the inter-vehicle distance setting unit 41 is connected to the preceding vehicle 100 suitable for performing the communication follow-up run, as in the case of setting the inter-vehicle distance at the time of autonomous follow-up travel control. The vehicle following time for communication follow-up travel stored in advance in the storage unit, the vehicle speed acquired by the vehicle speed acquisition unit 25, and the travel of the preceding vehicle 100 acquired by the preceding vehicle travel information acquisition unit 45 Set based on information. The inter-vehicle time for communication following traveling is set to be shorter than the inter-vehicle time for autonomous following traveling. For this reason, the inter-vehicle distance during the communication following traveling is set to be shorter than the inter-vehicle distance during the autonomous following traveling.

  Based on the position information of the preceding vehicle 100 acquired by the preceding vehicle traveling information acquisition unit 45, the communication follow-up traveling control ECU 40 has the same distance between the preceding vehicle 100 and the inter-vehicle distance set by the inter-vehicle distance setting unit 41. A signal is transmitted to the traveling control ECU 20 so as to adjust the speed of the vehicle 1. In this way, the driving control and braking force are adjusted according to the signal by the travel control ECU 20 to which the signal has been transmitted, and the inter-vehicle distance from the preceding vehicle 100 is maintained at a distance similar to the inter-vehicle distance set by the inter-vehicle distance setting unit 41. Thus, the follow-up traveling following the preceding vehicle 100 is performed.

  These follow-up running controls are used by giving priority to the communication follow-up running control between the communication follow-up running control and the autonomous follow-up running control, and are used depending on the communication state with the preceding vehicle 100 in the communication follow-up running control. Specifically, when the follow-up running control is performed, the communication follow-up running control ECU 40 determines whether or not the communication with the preceding vehicle 100 performed by the inter-vehicle communication device 15 is interrupted. The communication follow-up travel control ECU 40 transmits the determination result to the travel control ECU 20. The traveling control ECU 20 to which the determination result is transmitted switches the traveling mode by the traveling mode switching unit 28 according to the determination result.

  The travel mode switching unit 28 includes a communication follow-up travel control, an autonomous follow-up travel control, and a manual mode in which the driver performs all driving instructions by performing a driving operation without performing the follow-up travel control. Can be switched as the travel mode. When the travel mode is switched, the switching is also performed using the determination in the communication interruption determination unit 51.

  When the travel mode switching unit 28 switches the travel mode as described above, the determination that the driver is instructing to perform the follow-up travel and the communication with the preceding vehicle 100 is transmitted. In this case, the traveling mode is switched to the communication following traveling control. Further, when a determination that the communication with the preceding vehicle 100 is interrupted is transmitted in a state where the driver instructs to perform the follow-up running, the running mode is switched to the autonomous follow-up running control. In other words, when the driver has instructed to perform follow-up running, communication follow-up running control is performed when communication with the preceding vehicle 100 is possible, and autonomous follow-up is performed when communication with the preceding vehicle 100 is interrupted. Switch to travel control. Further, when the driver does not instruct to perform follow-up traveling, the traveling mode is switched to the manual mode without determining whether or not communication with the preceding vehicle 100 is being performed.

  When performing follow-up running, the communication follow-up running control and the autonomous follow-up running control are switched according to the state of communication with the preceding vehicle 100 as described above, and the running control is performed according to the running state of the preceding vehicle 100. Further, when the preceding vehicle 100 is decelerating when the communication following traveling control and the autonomous following traveling control are being performed, the preceding vehicle 100 is decelerated until the inter-vehicle time with respect to the preceding vehicle 100 elapses at any of the following traveling control. A deceleration having the same magnitude as the deceleration is generated in the own vehicle 1, that is, the own vehicle 1.

  During the follow-up running control, the host vehicle 1 is decelerated in accordance with the deceleration of the preceding vehicle 100 as described above. Here, the accelerations of both the own vehicle 1 and the preceding vehicle 100 when the preceding vehicle 100 decelerates are determined. Will be described.

  FIG. 4 is an explanatory diagram showing acceleration and relative acceleration between the preceding vehicle and the host vehicle when the preceding vehicle is decelerated. When the preceding vehicle 100 decelerates when the own vehicle 1 and the preceding vehicle 100 are traveling at the same speed, and the own vehicle 1 is traveling behind the preceding vehicle 100 with the relative acceleration of both vehicles being 0. Since the acceleration in the deceleration direction increases, the preceding vehicle acceleration 110, which is the acceleration of the preceding vehicle 100, increases. As described above, when the preceding vehicle 100 is decelerated while the speed of the own vehicle 1 is not changed and the preceding vehicle acceleration 110 is increased, an acceleration difference is generated between the preceding vehicle 100 and the own vehicle 1. As a result, the relative acceleration 115 between the host vehicle 1 and the preceding vehicle 100 increases.

Normally, when the vehicle decelerates, the deceleration increases as time elapses from a state where the deceleration is 0 to a predetermined deceleration such as the maximum deceleration according to the driving situation at that time. When it reaches speed, the vehicle continues to decelerate at that deceleration. Accordingly, the preceding vehicle 100, the preceding vehicle acceleration 110 is in a constant state at the maximum deceleration _{a 1_Max,} continued reduction in this maximum deceleration _{a 1_max.} Further, when the preceding vehicle acceleration 110 becomes constant at the maximum deceleration a 1 — _max as described above, the relative acceleration 115 also becomes constant.

  Thereafter, when the host vehicle 1 starts to decelerate, the host vehicle acceleration 111 that is the acceleration of the host vehicle 1 increases. As described above, when the host vehicle acceleration 111 increases while the preceding vehicle acceleration 110 is constant, the difference in acceleration between the host vehicle 1 and the preceding vehicle 100 starts to decrease, so the relative acceleration 115 that has been in a constant state is Start to get smaller. When the own vehicle acceleration 111 further increases and the own vehicle acceleration 111 becomes the same as the preceding vehicle acceleration 110, the relative acceleration 115 becomes zero.

  When the preceding vehicle 100 decelerates, the acceleration between the host vehicle 1 and the preceding vehicle 100 changes in this way. Based on this change in acceleration, the following description will be made on the inter-vehicle distance when the preceding vehicle 100 decelerates. When the vehicle is decelerated, the own vehicle 1 decelerates with respect to the deceleration of the preceding vehicle 100 due to a deceleration delay as described above. For this reason, although the relative acceleration 115 becomes large, when the relative acceleration 115 becomes large, the relative speed also changes. That is, when the own vehicle 1 has not started decelerating, the speed of the preceding vehicle 100 decreases with respect to the speed of the own vehicle 1 at a constant vehicle speed, and therefore the relative speed increases. . Thereby, the inter-vehicle distance between the own vehicle 1 and the preceding vehicle 100 becomes smaller as time passes.

  The change in the direction in which the relative speed increases becomes continuous until the deceleration of the own vehicle 1 becomes the same as the deceleration of the preceding vehicle 100 even if the own vehicle 1 starts to decelerate. For this reason, after deceleration of the preceding vehicle 100, the relative speed continues to increase until the deceleration of the own vehicle 1 becomes the same as the deceleration of the preceding vehicle 100, and the deceleration of the own vehicle 1 When it becomes the same size as the speed, the relative speed becomes constant. When the deceleration of the own vehicle 1 and the preceding vehicle 100 becomes the same magnitude, the relative speed becomes constant in this way, but the speed difference continues to exist, so even if the deceleration becomes the same magnitude The distance between the two cars continues to decrease.

Next, a change in the inter-vehicle distance when the preceding vehicle 100 and the host vehicle 1 are decelerated will be described. FIG. 5 is an explanatory diagram when the own vehicle decelerates after the start of deceleration of the preceding vehicle. FIG. 5 is an explanatory diagram for a case where the vehicle speed V ₀ = 100 km / h before deceleration, the deceleration a ₁ = 0.8 G, and the response delay dt = 1 s of the own vehicle 1 with respect to the deceleration of the preceding vehicle 100. ing. When the own vehicle 1 is traveling behind the preceding vehicle 100 at substantially the same vehicle speed with a predetermined inter-vehicle distance, when the preceding vehicle 100 starts to decelerate and the preceding vehicle acceleration 110 increases in the deceleration direction, The relative acceleration 115 of the preceding vehicle 100 with respect to the own vehicle 1 increases in the direction of deceleration with respect to the own vehicle 1. In this example, the case where the deceleration is 0.8 G will be described. Therefore, when the preceding vehicle acceleration 110 increases to 0.8 G, thereafter, the preceding vehicle 100 continues to decelerate at a deceleration of 0.8 G. For this reason, the relative acceleration 115 is constant for a predetermined period after the preceding vehicle acceleration 110 reaches 0.8G.

  Also, when the preceding vehicle 100 starts to decelerate and generates deceleration in this way, the preceding vehicle speed 117 decreases as time elapses, but when the host vehicle 1 is not decelerating. The relative speed 120 between the own vehicle 1 and the preceding vehicle 100 increases in the direction in which the speed of the preceding vehicle 100 is decelerated with respect to the speed of the own vehicle 1. As a result, the inter-vehicle distance 125 between the host vehicle 1 and the preceding vehicle 100 decreases with time.

  As the preceding vehicle 100 decelerates in this way, the inter-vehicle distance 125 between the preceding vehicle 100 and the own vehicle 1 is reduced. However, when the own vehicle 1 starts decelerating after the response delay time dt has elapsed, the own vehicle acceleration 111 is also increased. Similar to the preceding vehicle acceleration 110, it increases in the deceleration direction. As a result, the difference between the preceding vehicle acceleration 110 and the own vehicle acceleration 111 is reduced, so that the relative acceleration 115 of the preceding vehicle 100 that increases in the direction of deceleration relative to the own vehicle 1 is reduced. Further, in this example, when the own vehicle acceleration 111 increases to 0.8 G as with the preceding vehicle acceleration 110, the own vehicle 1 continues to decelerate at a deceleration of 0.8 G. When reaching 0.8G, the vehicle acceleration 111 becomes constant at 0.8G. In this case, there is no difference between the own vehicle acceleration 111 and the preceding vehicle acceleration 110, so the relative acceleration 115 becomes zero.

  Further, when the host vehicle 1 starts decelerating, the host vehicle speed 118 decreases, so the change in the relative speed 120 becomes gradual. When the host vehicle acceleration 111 becomes constant, the relative speed 120 also has a constant magnitude. become. Even when the preceding vehicle acceleration 110 and the own vehicle acceleration 111 are both equal to 0.8 G and the relative acceleration 115 becomes 0, the preceding vehicle acceleration 110 and the own vehicle acceleration 111 are delayed by the response delay of the own vehicle 1 to the deceleration of the preceding vehicle 100. While the vehicle speed 117 and the host vehicle speed 118 both decrease, the relative speed 120 is maintained at a constant magnitude. For this reason, the inter-vehicle distance 125 decreases as time elapses.

If the preceding vehicle 100 and the own vehicle 1 continue to decelerate at the same magnitude of deceleration in this state, the preceding vehicle 100 that started decelerating first stops first, and then the own vehicle 1 stops. . Thus, when the vehicle speed V ₀ = 100 km / h before deceleration, the deceleration a ₁ = 0.8 G, and the response delay dt = 1 s of the own vehicle 1 with respect to the deceleration of the preceding vehicle 100, the preceding vehicle 100 and the own vehicle When the vehicle 1 continues to decelerate until both stop, the jammed inter-vehicle distance 125 is about 27.7 m. This distance is a value obtained by multiplying the vehicle speed V ₀ = 100 km / h before deceleration by the response delay dt = 1s.

FIG. 6 is an explanatory diagram when the vehicle is decelerated at a small deceleration with respect to the deceleration described in FIG. FIG. 6 shows the response delay dt = 1 s of the own vehicle 1 with respect to the deceleration of the preceding vehicle 100 at the vehicle speed V ₀ = 100 km / h before deceleration as in the deceleration described with reference to FIG. It is explanatory drawing about the case where it decelerates by ₁ = 0.4G. As described above, even when the deceleration is 0.4G, when the preceding vehicle 100 decelerates, the preceding vehicle 100 increases in deceleration until the preceding vehicle acceleration 110 becomes 0.4G, and the preceding vehicle acceleration is increased. When 110 reaches 0.4G, the preceding vehicle 100 continues to decelerate at a deceleration of 0.4G. Further, when the preceding vehicle 100 is decelerated and the host vehicle 1 is in a state before being decelerated, the relative acceleration 115 increases as the preceding vehicle acceleration 110 increases, and decreases when the preceding vehicle acceleration 110 reaches 0.4G. The speed is maintained for a predetermined period with a size smaller than that of 0.8G.

  Further, when the preceding vehicle 100 decelerates at a deceleration of 0.4 G in this way, the preceding vehicle speed 117 decreases with a gentler slope than when the deceleration is 0.8 G. For this reason, when the own vehicle 1 is not decelerating, the relative speed 120 between the own vehicle 1 and the preceding vehicle 100 increases with a gentler slope than when the deceleration is 0.8G. As a result, the inter-vehicle distance 125 between the host vehicle 1 and the preceding vehicle 100 becomes smaller with a gentler slope as time passes than when the deceleration is 0.8G.

  After the preceding vehicle 100 starts decelerating in this way, when the own vehicle 1 starts decelerating after the response delay time dt has elapsed, the own vehicle acceleration 111 increases to 0.4 G as with the preceding vehicle acceleration 110, and the own vehicle When the acceleration 111 reaches 0.4G, the host vehicle acceleration 111 becomes constant at 0.4G. As a result, the relative acceleration 115 becomes zero.

  When the own vehicle 1 starts decelerating and the own vehicle acceleration 111 becomes constant, the relative speed 120 also becomes a constant magnitude as in the case where the deceleration is 0.8G. In addition, when the vehicle is decelerated at a deceleration of 0.4 G as described above, the vehicle 1 is decelerated with respect to the deceleration of the preceding vehicle 100 even when the relative acceleration 115 is 0, as in the case of deceleration at a deceleration of 0.8 G. Due to the delay in response to deceleration, the relative speed 120 is maintained at a constant magnitude, and the inter-vehicle distance 125 decreases with time.

  In this state, if deceleration is continued until both the preceding vehicle 100 and the host vehicle 1 stop, the jammed inter-vehicle distance 125 becomes about 27.7 m as in the case where the deceleration is 0.8G. That is, when the initial speed of the preceding vehicle 100 and the own vehicle 1 is the same vehicle speed and the deceleration at the time of deceleration is the same magnitude, the jammed inter-vehicle distance 125 corresponds to the response delay regardless of the magnitude of the deceleration. Become a distance.

  If the initial speed and the deceleration of the preceding vehicle 100 and the host vehicle 1 are the same, the distance between the cars 125 at the time of deceleration is the same distance regardless of the magnitude of the deceleration. The initial speeds of the preceding vehicle 100 and the host vehicle 1 affect the inter-vehicle distance 125 that is clogged during deceleration. Next, the case of different initial speeds will be described.

FIG. 7 is an explanatory diagram when the initial speed is slower than the deceleration described in FIG. FIG. 7 shows that the deceleration a ₁ = 0.8 G at the time of deceleration and the response delay dt = 1 s of the own vehicle 1 with respect to the deceleration of the preceding vehicle 100 as in the deceleration described with reference to FIG. It has become explanatory diagram of a case where the vehicle speed _V 0 = 50km / h.

  As described above, even when the vehicle speed before deceleration is slow, when the vehicle is decelerated at a deceleration of 0.8 G, the preceding vehicle acceleration 110 and the host vehicle acceleration have the same inclination as when the vehicle speed before deceleration is 100 km / h. 111 changes, and the relative acceleration 115 changes similarly to the case where the vehicle speed before deceleration is 100 km / h. As a result, the preceding vehicle speed 117 and the host vehicle speed 118 change in the same manner as when the vehicle speed before deceleration is 100 km / h. Therefore, the relative speed 120 and the inter-vehicle distance 125 are also the vehicle speed before deceleration of 100 km / h. Change the same as the case.

However, when the speed before deceleration is 50 km / h, the distance from the start of deceleration to the stop is shortened, and the jammed inter-vehicle distance 125 is shortened. In other words, after the start of deceleration of the preceding vehicle 100, when the host vehicle 1 decelerates with a response delay, the degree of change in the inter-vehicle distance 125 is the same as when the speed before deceleration is 100 km / h, When the speed before deceleration is 50 km / h, the initial speed is slow, so the time from the start of deceleration until the vehicle stops is shortened. For this reason, the inter-vehicle distance 125 jammed at the time of deceleration is shortened. Specifically, the jammed inter-vehicle distance 125 is about 13.9 m obtained by multiplying the vehicle speed V ₀ = 50 km / h before deceleration by the response delay dt = 1s. Become.

  As described above, the inter-vehicle distance 125 that is blocked when the host vehicle 1 decelerates at the same deceleration as that of the preceding vehicle 100 is the response delay time × the initial speed regardless of the deceleration at the time of deceleration. For this reason, regardless of the deceleration, the inter-vehicle distance 125 that is clogged becomes smaller as the response delay time becomes shorter, and if the response delay time is 0 s, that is, if the same deceleration as the preceding vehicle 100 can be performed, the inter-vehicle distance 125 after deceleration is The distance is indicated by the same inter-vehicle time as the inter-vehicle time before deceleration.

  When the host vehicle 1 is traveling behind the preceding vehicle 100, the inter-vehicle distance 125 that is clogged when the host vehicle 1 also decelerates due to the deceleration of the preceding vehicle 100 is thus greatly affected by the response delay time. Next, a description will be given of a deceleration state that can reduce the possibility of a rear-end collision when the preceding vehicle 100 and the host vehicle 1 are decelerated.

  FIG. 8 is an explanatory diagram showing the relationship between the acceleration, relative acceleration, and relative speed between the host vehicle and the preceding vehicle during deceleration. To explain the complicated phenomenon during deceleration simply abstracted, when the preceding vehicle 100 and the own vehicle 1 decelerate, the own vehicle 1 reacts with the same reaction time as the inter-vehicle time after the preceding vehicle 100 decelerates. Thus, by decelerating at a deceleration greater than the deceleration of the preceding vehicle 100, the possibility of a rear-end collision can be reduced. For example, when the inter-vehicle time is 0.8 s, after the preceding vehicle 100 starts decelerating, it reacts at 0.8 s and starts decelerating, and then decelerates at a deceleration greater than the deceleration of the preceding vehicle 100. The vehicle 1 can reduce the possibility that a rear-end collision with the preceding vehicle 100 occurs.

That is, when the jerk, which is the degree of change in deceleration with respect to the elapsed time, is the same for the preceding vehicle 100 and the own vehicle 1, the reaction time t _delay that is the response delay time of the own vehicle 1 with respect to the braking of the preceding vehicle 100 If the relationship with the set inter-vehicle time τ can satisfy (t _delay ≦ τ), the possibility of a rear-end collision can be reduced. That is, by setting the relative speed generated by the response delay to a certain value or less, the possibility of a rear-end collision can be reduced.

  The case where reduction in the possibility of rear-end collision at the time of deceleration is considered from the viewpoint of relative speed will be described. First, when the deceleration jerk is the same in the own vehicle 1 and the preceding vehicle 100, the preceding vehicle 100 is decelerated. The preceding vehicle acceleration 110 indicating deceleration and the own vehicle acceleration 111 indicating deceleration when the host vehicle 1 is decelerating have the same inclination with respect to the elapsed time.

Therefore, when the preceding vehicle acceleration 110 and the own vehicle acceleration 111 are the same jerk, and the maximum value of the own vehicle acceleration 111 is larger than the preceding vehicle maximum deceleration a _{1_max} that is the maximum value of the preceding vehicle acceleration 110, the own vehicle When the acceleration 111 occurs with a _delay of the reaction time t _delay with respect to the preceding vehicle acceleration 110, the total amount of acceleration difference caused by the response delay time is the slope portion between the preceding vehicle acceleration 110 and the own vehicle acceleration 111. The area S _{a of the} parallelogram surrounded by the preceding vehicle maximum deceleration a 1 — _max and the minimum deceleration value (0).

When the total amount of the difference in acceleration (deceleration) is expressed by relative acceleration, when the preceding vehicle 100 starts to decelerate and the own vehicle 1 does not start decelerating due to a response delay, the maximum value of the relative acceleration is The preceding vehicle maximum deceleration _{a1_max} is obtained. When the response delay time of the _host vehicle 1 occurs when the preceding vehicle 100 decelerates, the preceding vehicle maximum deceleration a _{1_max} occurs as a relative acceleration during the response delay time, that is, during the reaction time t _delay. It will be. Therefore, the total amount of relative acceleration due to response delay time becomes the preceding vehicle maximum deceleration _{a 1_Max} value obtained by multiplying the response time _{t delay} in, surrounded by the preceding vehicle maximum deceleration _{a 1_Max} and reaction time _{t delay} This can be indicated by the area _{Sr of the} portion.

As described above, when the response delay occurs, the total amount of acceleration and relative acceleration can be indicated by the parallelogram area S _{a of} acceleration and the area S _{r of} relative acceleration. It can be calculated by multiplying the deceleration a 1 — _max by the reaction time t _delay . In addition, in order to reduce the possibility of a rear-end collision when the host vehicle 1 decelerates after the preceding vehicle 100 starts decelerating, the relationship between the reaction time t _delay and the set inter-vehicle time τ is (t _delay ≦ τ If it can be satisfied, it can be expressed by the following formula (1).
S _r (relative acceleration area) = S _a (parallelogram area) ≦ τ (set inter-vehicle time) · a _{1_max} (preceding vehicle maximum deceleration) (1)

The relative acceleration area S _r is the total amount of acceleration during the reaction time t _delay , and in other words represents the relative speed V _r between the host vehicle 1 and the preceding vehicle 100 after the reaction time t _delay elapses. It will be. If the jerk of the deceleration of the preceding vehicle 100 and the host vehicle 1 is the same, the relationship {t _delay (reaction time) ≦ τ (set inter-vehicle time)} is used to reduce the possibility of rear-end collision. As long as V _{r_max} is the maximum value of the relative speed that is the distance immediately before the own vehicle 1 collides with the preceding vehicle 100 at the end of deceleration of the preceding vehicle 100 and the own vehicle 1, The maximum value V _{r_max} is a value obtained by multiplying the set inter-vehicle time τ and the preceding vehicle maximum deceleration a _{1_max} . For this reason, by setting the relative speed V _r generated due to the response delay of the _host vehicle 1 to be equal to or less than the maximum value V _{r_max} of the relative speed as shown in the following equation (2), the possibility of a rear-end collision can be reduced. .
V _r (relative speed) ≦ V _{r_max} = τ (set inter-vehicle time) · a _{1_max} (preceding vehicle maximum deceleration) (2)

  In this equation (2), there is a condition for reducing the possibility of a rear-end collision including not only the start of braking but also the steady braking region. For this reason, when the preceding vehicle 100 decelerates, even if the start of braking of the host vehicle 1 is delayed, the rear-end collision to the preceding vehicle 100 may occur by finally performing braking satisfying the expression (2). Can be reduced. That is, after the start of braking, by performing appropriate feedback control such as detecting the relative speed with the preceding vehicle 100 using the radar 12, and finally performing braking satisfying Equation (2), the occurrence of a rear-end collision is generated. It is possible to secure time for performing the control for reducing the possibility.

  FIG. 9 is an explanatory diagram of acceleration between the preceding vehicle and the host vehicle during deceleration during the follow-up running control. When the host vehicle 1 is decelerated after the preceding vehicle 100 starts decelerating, the response delay of the host vehicle 1 is greatly involved as described above, and therefore a rear-end collision may occur when traveling behind the preceding vehicle 100. In order to reduce this, it is necessary to travel in consideration of the response delay of the host vehicle 1. Next, the case where the inter-vehicle time is set in consideration of the response delay at the time of deceleration will be described. For example, when the preceding vehicle 100 suddenly brakes during follow-up traveling control with an inter-vehicle time of 0.8 s, the response delay is about communication delay (0.1 s) in the communication following traveling control. Deceleration can be performed at almost the same timing as deceleration. For this reason, in the communication follow-up running control, it is possible to start braking at a sufficient speed when the follow-up running is performed with an inter-vehicle time of 0.8 s.

  In addition, when autonomous follow-up running control is performed due to communication interruption during communication follow-up running, if the vehicle is decelerated at a deceleration greater than the deceleration of the preceding vehicle 100 within 0.8 s, which is the set inter-vehicle time, The possibility of rear-end collision can be reduced. During autonomous follow-up running control, the possibility of a rear-end collision can be reduced by estimating the deceleration of the preceding vehicle 100 based on the detection result of the radar 12 and generating the estimated deceleration within 0.8 s.

  In addition, the initial relative speed becomes 0 during follow-up running at a steady speed, but in the case of catch-up or interruption, an initial relative speed is generated. For example, when the vehicle speed of the preceding vehicle 100 when the preceding vehicle 100 starts to decelerate is 80 km / h and the vehicle speed of the host vehicle 1 at that time is 100 km / h, the initial relative speed is 20 km / h. Become. The control that can reduce the possibility of a rear-end collision even when the preceding vehicle 100 decelerates suddenly when there is an initial relative speed will be described below. The sum of the relative speed due to a response delay occurring between vehicles and the initial relative speed. Defines the equivalent reaction time that is equal to the relative speed margin between vehicles. When the host vehicle 1 is decelerated, the deceleration is controlled so that the equivalent reaction time does not exceed the set inter-vehicle time.

FIG. 10 is an explanatory diagram of the equivalent reaction time. The equivalent reaction time will be the same as the relative acceleration area S _r (see FIG. 8) when the value corresponding to the initial relative speed V _r0 is added, and the height is the preceding vehicle. The size of the base of the parallelogram that _{gives the} maximum deceleration a _{1_max} is the equivalent reaction time x. Relative acceleration area S _r has extremely preceding vehicle maximum deceleration a _{1_Max} a value obtained by multiplying the set inter-vehicle time tau, expressed these formula, the following equation (3).
a 1 — _max · x + V _r0 = a 1 — _max · τ (3)

When this equation (3) is transformed into an equation for obtaining the equivalent reaction time x, the following equation (4) is obtained.
x = _τ− (V _r0 / a 1 — _max ) (4)

As is apparent from this equation (4), by causing the own vehicle 1 to generate a deceleration equal to or higher than the same deceleration as that of the preceding vehicle 100 within a time obtained by subtracting the initial relative speed V _r0 corresponding amount from the set inter-vehicle time τ. Even when the initial relative speed V _r0 is generated when the preceding vehicle 100 is decelerated, the possibility of a rear-end collision with the preceding vehicle 100 can be reduced.

In addition, the equivalent reaction time x is a time during which it is possible to perform control for reducing the possibility of a rear-end collision between the host vehicle 1 and the preceding vehicle 100 by comparing with the set inter-vehicle time τ. It can be handled in the same manner as the reaction time t _delay when the velocity V _r0 is not generated. That is, even when the initial relative velocity V _r0 is generated, by converting to the equivalent reaction time x, the equivalent reaction time x = t _delay is treated as in the case where the initial relative velocity V _r0 is not generated. By deriving an equivalent reaction time that satisfies {t _delay (equivalent reaction time) ≦ τ (set inter-vehicle time)}, it is possible to perform a braking control that can reduce the possibility of a rear-end collision.

  When the host vehicle 1 is decelerated in accordance with the deceleration of the preceding vehicle 100, the deceleration of the host vehicle 1 that can satisfy the above-described equations using the deceleration of the preceding vehicle 100 and the inter-vehicle time as described above. By deriving the speed and decelerating the host vehicle 1, the possibility of a rear-end collision with the preceding vehicle 100 can be reduced. Next, control that can reduce the possibility of a rear-end collision with the preceding vehicle 100 using the above-described conditions when the preceding vehicle 100 is decelerated during the following traveling control is divided into communication following traveling control and autonomous following traveling control. I will explain it. First, in the communication follow-up running control, the running information of the preceding vehicle 100 is obtained by inter-vehicle communication and the follow-up running control is performed. Therefore, when the preceding vehicle 100 decelerates, the information is also obtained. For example, when the driver of the preceding vehicle 100 decelerates by performing a braking operation on the brake pedal, information on the braking operation is acquired by the preceding vehicle travel information acquisition unit 45. In addition, when the preceding vehicle 100 is performing driving support control of the driver, such as when the preceding vehicle 100 is performing follow-up driving control on the vehicle ahead of the preceding vehicle 100, when the preceding vehicle 100 is decelerated by the driving support control The preceding vehicle travel information acquisition unit 45 acquires the information on the deceleration control.

  The communication follow-up travel control ECU 40 that has acquired the travel information at the time of deceleration of the preceding vehicle 100 using inter-vehicle communication by the preceding vehicle travel information acquisition unit 45 is based on the information at the time of deceleration acquired by the preceding vehicle travel information acquisition unit 45. The preceding vehicle maximum deceleration deriving unit 46 derives the maximum deceleration of the preceding vehicle 100. When the maximum deceleration of the preceding vehicle 100 is derived by the preceding vehicle maximum deceleration deriving unit 46, for example, when information on a braking operation is used as information when the preceding vehicle 100 decelerates, the driver presses the brake pedal. Based on the operation amount and the operation speed at the time of operation, the deceleration generated by the driver's braking operation is derived, and the maximum deceleration when this braking operation is performed is calculated as the preceding vehicle maximum deceleration deriving unit. Derived at 46.

  Further, when information on deceleration control when the preceding vehicle 100 is decelerated by the driving support control is used as information at the time of deceleration of the preceding vehicle 100, the information on the preceding vehicle 100 is based on the deceleration instruction instructed by the driving support control. The maximum deceleration when the deceleration is acquired and this deceleration instruction is issued is derived by the preceding vehicle maximum deceleration deriving unit 46. The preceding vehicle maximum deceleration, which is the maximum deceleration of the preceding vehicle 100 derived by the preceding vehicle maximum deceleration deriving unit 46 of the communication following traveling control ECU 40, is transmitted to the traveling control ECU 20, and based on the preceding vehicle maximum deceleration, The deceleration calculation unit 33 of the travel control ECU 20 calculates the deceleration of the host vehicle 1.

When the deceleration calculation unit 33 calculates the deceleration of the host vehicle 1, the deceleration calculation unit 33 calculates the deceleration based on the inter-vehicle time that is set based on the vehicle speed of the host vehicle 1 before deceleration. The amount of deceleration displacement, that is, the degree of change in the deceleration with respect to the elapsed time is calculated so that the deceleration of the host vehicle 1 is the same as the deceleration of the preceding vehicle 100. When calculating the degree of change in the deceleration, it is calculated as a controllable value including the deceleration after the rise of the deceleration. Specifically, the preset inter-vehicle time τ set for communication follow-up travel and the preceding vehicle maximum deceleration a _{1_max} that is the maximum deceleration of the preceding vehicle 100 derived by the preceding vehicle maximum deceleration deriving unit 46 are obtained. Using (V _{r_max} = τ · a _{1_max} ), which is the above equation (2), is calculated by the deceleration relative speed calculation unit 35 to calculate the maximum value V _{r_max} of the relative speed. Thereby, the value which can control the deceleration of the own vehicle 1 is calculated including the time after the rising of the deceleration. That is, the maximum value V _{r_max} of the relative speed _{sets the} deceleration when the _host vehicle 1 is decelerated to the same magnitude as the deceleration of the preceding vehicle 100 when the inter-vehicle time elapses from the current vehicle speed. It is a value that can realize the amount of change in the deceleration required for.

  On the other hand, when performing autonomous follow-up running control, the autonomous follow-up running control ECU 60 derives the deceleration of the preceding vehicle 100 based on the inter-vehicle distance from the preceding vehicle 100 acquired by the front state acquisition unit 61. That is, the preceding vehicle deceleration deriving unit 63 derives the deceleration at the time of deceleration of the preceding vehicle 100 based on the degree of change in the inter-vehicle distance between the own vehicle 1 and the preceding vehicle 100 acquired by the front state acquiring unit 61.

  In addition, the preceding vehicle deceleration deriving unit 63 determines the maximum deceleration of the preceding vehicle that is the maximum deceleration of the preceding vehicle 100 based on the derived degree of change in the deceleration of the preceding vehicle 100, the vehicle speed, the traveling environment at that time, and the like. Deriving speed. The preceding vehicle maximum deceleration derived by the preceding vehicle deceleration deriving unit 63 of the autonomous tracking traveling control ECU 60 is transmitted to the traveling control ECU 20 as traveling information of the preceding vehicle 100, and the traveling control ECU 20 is based on the preceding vehicle maximum deceleration. The deceleration calculation unit 33 calculates the deceleration of the host vehicle 1.

When the deceleration calculation unit 33 calculates the deceleration of the host vehicle 1 during the autonomous follow-up running control, as in the communication follow-up running control, the inter-vehicle time set based on the vehicle speed of the host vehicle 1 before deceleration is set. Calculate based on That is, by using the set inter-vehicle time τ set in advance for autonomous following traveling and the preceding vehicle maximum deceleration a _{1_max} that is the maximum deceleration of the preceding vehicle 100 derived by the preceding vehicle deceleration deriving unit 63, Equation (2) (V _{r_max} = τ · a _{1_max} ) is calculated by the deceleration relative speed calculation unit 35 to calculate the maximum value V _{r_max} of the relative speed. As a result, the deceleration when the host vehicle 1 is decelerated can be controlled including the time after the start of the deceleration, and when the inter-vehicle time elapses from the current vehicle speed, the deceleration is the same as the deceleration of the preceding vehicle 100. The maximum value V _{r_max} of the relative speed, which is a value that can realize the amount of change in deceleration necessary for the speed, is calculated.

  In the communication following traveling control, since traveling information of the preceding vehicle 100 is acquired by inter-vehicle communication, the deceleration and the deceleration start timing of the preceding vehicle 100 can be recognized more accurately. Then, the deceleration of the preceding vehicle 100 is derived based on the inter-vehicle distance between the host vehicle 1 and the preceding vehicle 100. For this reason, the deceleration of the preceding vehicle 100 derived by the autonomous following traveling control is less accurate than the deceleration of the preceding vehicle 100 derived by the communication following traveling control. As a result, in the autonomous following traveling control, it is difficult to perform the deceleration control of the own vehicle 1 that is optimal for the relative traveling state between the actual preceding vehicle 100 and the own vehicle 1 compared to the communication following traveling control. Even in this autonomous follow-up running control, it is preferable to calculate the deceleration of the host vehicle 1 with the goal of the time when the inter-vehicle time elapses as much as possible, as in the communication follow-up running control.

If the deceleration of the own vehicle 1 is derived based on the deceleration of the preceding vehicle 100 as described above in the communication following traveling control or the autonomous following traveling control, the brake control unit 22 applies the derived deceleration to the own vehicle 1. In order to generate this, the brake hydraulic pressure control device 8 is controlled according to the derived deceleration. At that time, in either case of the communication follow-up running control and the autonomous follow-up running control, the relative speed calculation unit 34 calculates the relative speed V _r with the preceding vehicle 100 from the degree of change in the detection result of the radar 12, The deceleration is controlled so that the relative speed V _r becomes equal to or less than the maximum value V _{r_max} of the relative speed calculated by the deceleration relative speed calculation unit 35. Therefore, when the braking force is actually adjusted to cause the own vehicle 1 to generate a deceleration, the deceleration is controlled including the control after the start of the deceleration, and the deceleration feedback control is performed. Thereby, the calculated deceleration is appropriately generated in the own vehicle 1.

  Further, during the communication follow-up running control, the control is performed while determining the communication interruption. However, in order to more reliably reduce the possibility of a rear-end collision with the preceding vehicle 100 at the time of the communication interruption, the communication interruption occurs. Once started, preparation for brake control is started during communication interruption before the communication interruption determination is finalized. FIG. 11 is an explanatory diagram of control at the time of occurrence of communication interruption. For example, a case where communication follow-up running control is performed with an inter-vehicle time of 0.8 s will be described. When the inter-vehicle time is 0.8 s, a deceleration having the same magnitude as the deceleration of the preceding vehicle 100 is generated in the own vehicle 1. In the case where it is possible to reduce the possibility of a rear-end collision with the preceding vehicle 100, the deceleration of the host vehicle 1 is started within 0.8 s after the preceding vehicle 100 starts to decelerate. That is, after the preceding vehicle acceleration 110 rises, the host vehicle acceleration 111 rises within 0.8 s, but a communication delay of about 0.1 s occurs in the inter-vehicle communication used for the communication following traveling control. For this reason, the communication detection preceding vehicle acceleration 130, which is the preceding vehicle acceleration 110 that can be detected by the own vehicle 1 by inter-vehicle communication at the time of communication following traveling control, is detected by the own vehicle 1 0.1s after the preceding vehicle acceleration 110. .

  The deceleration of the preceding vehicle 100 can also be detected by the radar 12, and when the communication is interrupted during communication follow-up running control, the deceleration of the preceding vehicle 100 is detected by the radar 12, but the deceleration of the preceding vehicle 100 is detected by the radar 12. In the case of detecting with, radar recognition delay of about 0.3 s occurs. For this reason, the radar detection preceding vehicle acceleration 131 which is the preceding vehicle acceleration 110 that can be detected by the radar 12 by the own vehicle 1 is detected by the own vehicle 1 0.3 s after the preceding vehicle acceleration 110.

  In addition, when a control signal is transmitted to the brake hydraulic pressure control device 8 and an actual braking force is generated by an actuator such as a wheel cylinder, a response delay of about 0.3 s occurs. For this reason, the deceleration control is performed so that the reaction time of the own vehicle 1 after the deceleration of the preceding vehicle 100 is equal to or less than the set inter-vehicle time in which the inter-vehicle time is set between the own vehicle 1 and the preceding vehicle 100. In this case, at the latest 0.3 s before the set inter-vehicle time, a deceleration instruction is issued with the own vehicle requested acceleration 135 that causes the own vehicle 1 to generate the own vehicle acceleration 111. For this reason, when communication is interrupted after the preceding vehicle travel information acquisition unit 45 acquires that the preceding vehicle 100 has started decelerating during communication following travel control, 0.3 s before the set inter-vehicle time, that is, the preceding It waits for the communication interruption determination until 0.5 s after the start of deceleration of the car 100.

  Specifically, when communication is interrupted after the preceding vehicle 100 starts decelerating, detection by the radar 12 is performed even if communication is interrupted until 0.3 s at which the traveling state of the preceding vehicle 100 can be detected by the radar 12 elapses. Since the deceleration control of the host vehicle 1 can be performed using the result, it waits for communication to return until 0.3 s has elapsed. When 0.3 s elapses after the preceding vehicle 100 starts decelerating, the deceleration control of the host vehicle 1 cannot be performed using the detection result of the radar 12, so that the hydraulic pressure generated by the brake hydraulic control device 8 is increased. In the prepared state, wait for communication interruption determination.

  In this state, if communication does not return within 0.5 s after the preceding vehicle 100 starts to decelerate, the communication interruption determination unit 51 determines communication interruption, and the brake control unit 22 sends a control signal to the brake hydraulic pressure control device 8. Is transmitted, and a deceleration instruction is issued at the requested acceleration 135 of the host vehicle. As a result, the own vehicle acceleration 111 is generated after the response delay of the actuator has elapsed, that is, after 0.3 s. That is, when the communication interruption time exceeds the communication interruption determination time during the vehicle-to-vehicle communication, the vehicle-to-vehicle communication is stopped, and the following traveling control is switched from the communication following traveling control to the autonomous following traveling control.

On the other hand, when communication is restored within 0.5 s after the start of deceleration of the preceding vehicle 100 in a state where the hydraulic pressure generated by the brake hydraulic control device 8 is prepared, the hydraulic pressure is set to 0 and normal communication follow-up traveling is performed. Return to control. That is, the time t ₁ when the preceding vehicle 100 starts decelerating and the radar 12 can detect the preceding vehicle 100 after the radar recognition delay, and the time t ₂ when the vehicle is requested to decelerate at the requested acceleration 135 Does not satisfy the relationship of (t ₁ ≦ t ₂ ), when a communication interruption occurs, a request to the brake actuator before the communication interruption determination is started. In other words, when performing communication follow-up running control, the detection delay from the start time t ₀ of the deceleration control of the preceding vehicle 100, until the vehicle 1 is detected based on a start of the deceleration control of the preceding vehicle 100 in the travel information Radar recognition delay τ _sensor , which is the time, actuator response delay τ _act , which is the control response delay time from when the vehicle 1 transmits the deceleration control signal until the vehicle 1 actually starts deceleration control, and the preceding vehicle It is a requirement that the relationship between the set inter-vehicle time τ _set which is the inter-vehicle time between the vehicle 100 and the host vehicle 1 satisfies (τ _sensor + τ _act ≦ τ _set ). When the radar recognition delay τ _sensor , the actuator response delay τ _act, and the set inter-vehicle time τ _set do not satisfy this requirement, control at the time of communication interruption is performed.

The communication interruption determining time requirements, a communication interruption determining time tau _com, an actuator response delay tau _act, the communication interruption determining time tau _com that the relationship between the set inter-vehicle time tau _{The set} becomes _{(τ com + τ act ≦ τ} set) It has become. For this reason, a deceleration command is started before the actuator response delay τ _act before the set inter-vehicle time τ _set . That is, it is possible to endure the determination of the communication interruption until the actuator response delay τ _act before the set inter-vehicle time τ _set .

The set inter-vehicle time τ _set is set to be equal to or greater than the sum of the radar recognition delay τ _sensor and the actuator response delay τ _act , but the detection state of the radar 12 and the operation state of an actuator such as a brake device are It may change depending on the environment at the time of 1 driving. Therefore, radar recognition delay _{tau: sensor} or an actuator response delay tau _act may change at least one of radar recognition delay _{tau: sensor} or actuator response delay tau _act, in accordance with the running state of the vehicle 1 including the driving time of the environment The set inter-vehicle time τ _set is preferably set to be not less than the sum of the changed radar recognition delay τ _sensor and the actuator response delay τ _act .

For example, the hydraulic oil whose hydraulic pressure is controlled by the brake hydraulic pressure control device 8 when operating the brake device has a high viscosity when the temperature is low, and therefore, the rising response time of the hydraulic pressure tends to be delayed. For this reason, when the temperature around the own vehicle 1 is low and the temperature of the hydraulic fluid that operates the brake device is low, the actuator response delay τ _act is increased to set the set inter-vehicle time τ _set . That is, in this case, the set inter-vehicle time τ _set is also increased.

In this state, the vehicle 1 travels for a predetermined time and brakes with the brake device. When the temperature of the hydraulic oil rises due to the heat generated during braking, the hydraulic oil rises until the response time of the hydraulic oil rises. The actuator response delay τ _act is reduced. In accordance with this, the set inter-vehicle time τ _set is also _set smaller than when the actuator response delay τ _act is large.

Further, when the communication interruption determination is made when the preceding vehicle 100 is decelerated during the communication follow-up running control, the driver is notified that the communication with the preceding vehicle 100 is interrupted. For example, an alarm sound is emitted when the communication interruption determination time τ _com has elapsed, thereby informing the driver that communication has been interrupted. The driver performs a brake operation after a predetermined time has elapsed after hearing this warning. That is, the driver operates the brake after the _driver brake operation delay τ _driver elapses after the communication interruption is determined due to the driver's own reaction delay after hearing the warning.

As described above, even when communication is interrupted during communication follow-up running control, the equivalent reaction time t _delay and the set inter-vehicle time τ are (t _delay ≦ τ) in the region A until the deceleration of the host vehicle 1 rises. In order to satisfy this relationship, a command to start deceleration of the preceding vehicle 100 or more is started earlier by the actuator response delay τ _act than the set inter-vehicle time τ _set . In the region B after the deceleration of the _host vehicle 1 rises, the relative speed V _r , the set inter-vehicle time τ, and the preceding vehicle maximum deceleration a _{1_max} (V _r ≦ V _{r_max} = τ · a _{1_max} ). In order to satisfy this relationship, appropriate feedback control is performed based on the detection result of the radar 12 even after the deceleration of the host vehicle 1 rises.

  Further, when another vehicle is interrupted between the preceding vehicle 100 and the host vehicle 1 during the communication following traveling control or the autonomous following traveling control, the inter-vehicle time between the vehicle and the own vehicle 1 is The inter-vehicle time is different from the inter-vehicle time set in the following traveling control or the autonomous following traveling control. In this case, the radar 12 detects this vehicle and sets the inter-vehicle time based on the detection result.

  That is, in both cases of the communication follow-up running control and the autonomous follow-up running control, the state following the own vehicle 1 is detected by the radar 12 during the follow-up running control, and the autonomous follow-up running control ECU 60 has the detection result. The follow-up running control is performed while being acquired by the front state obtaining unit 61, but the relative speed with the own vehicle 1 is too large at a position closer to the distance between the preceding vehicle 100 and the own vehicle 1 during the follow-up running control. If no obstacle appears, this obstacle is determined as another vehicle. In this case, this vehicle is determined as the preceding vehicle 100, the front state acquisition unit 61 acquires the inter-vehicle distance from the new preceding vehicle 100 based on the detection result of the radar 12, and is acquired by the front state acquisition unit 61. The inter-vehicle time detection unit 30 detects the inter-vehicle time based on the inter-vehicle distance and the current vehicle speed acquired by the vehicle speed acquisition unit 25.

  During communication follow-up running control or autonomous follow-up running control, when a new preceding vehicle 100 appears due to another vehicle interrupting in front of the host vehicle 1, the inter-vehicle time detected by the inter-vehicle time detection unit 30 in this way Follow-up running control is performed based on time. For this reason, when the new preceding vehicle 100 decelerates, the own vehicle 1 applies a deceleration having the same magnitude as the deceleration with the preceding vehicle 100 until the inter-vehicle time detected by the inter-vehicle time detection unit 30 elapses. To generate.

Since the vehicle control device 2 described above sets the set inter-vehicle time τ _set at a time equal to or greater than the sum of the radar recognition delay τ _sensor and the actuator response delay τ _act during the follow-up travel control performed based on the travel information of the preceding vehicle 100, Even when the vehicle 100 decelerates, it is possible to reduce the possibility of the rear collision of the host vehicle 1 with the preceding vehicle 100, and the follow-up traveling control can be appropriately performed. Furthermore, since at least one of the radar recognition delay τ _{sensor and the} actuator response delay τ _act is changed according to the environment and the traveling situation when the host vehicle 1 is traveling, the set inter-vehicle time τ _set during the following traveling control is It is possible to change appropriately according to the current driving situation and perform more appropriate follow-up driving control. As a result, inter-vehicle distance control during follow-up traveling can be performed more appropriately.

Further, since the ambient temperature of the vehicle 1 is used as the environment when the vehicle 1 is used for changing the radar recognition delay τ _sensor and the actuator response delay τ _act , the radar recognition delay τ _sensor and the actuator response delay τ _The set inter-vehicle time τ _set that is set based on the _act can be set to an inter-vehicle time suitable for the traveling state of the host vehicle 1 that changes according to the environment during traveling. As a result, inter-vehicle distance control during follow-up traveling can be performed more appropriately.

In the vehicle control device 2 according to the embodiment, the radar recognition delay τ _sensor and the actuator response delay τ _act are changed according to the ambient temperature of the vehicle 1, but the radar recognition delay τ _sensor and the actuator response delay are changed. τ _act may be changed based on other than this. For example, the radar recognition delay τ _sensor or the like may be changed in accordance with the form of the laser 12 that is the forward situation detection means used when acquiring the running information of the preceding vehicle 100 as the running situation of the host vehicle 1. That is, the radar 12 can use different forms of detection means such as a laser radar using a laser as a detection wave used when detecting a detection target, or a millimeter wave radar using a millimeter wave. Depending on the transmission characteristics, reflection characteristics, and reception characteristics may differ. For this reason, depending on the form of the radar 12, the time for detecting the state ahead of the host vehicle 1, that is, the traveling state of the preceding vehicle 100, may be different. Therefore, depending on the form of the radar 12, the radar recognition delay τ _sensor May be changed.

  In addition, the vehicle 1 including the vehicle control device 2 includes not only the engine 5 as a power source but also a motor (not shown) that generates power by electricity, and appropriately uses the power generated by the engine 5 and the power generated by the motor. It may be a so-called hybrid vehicle that can travel by being properly used. In the case of such a hybrid vehicle, the power source is switched depending on the traveling state, so that the driving force generation mode at the time of acceleration is appropriately switched, and the driving force generation mode at the time of acceleration of the host vehicle 1 also during the follow-up driving control. However, the above-described control as to whether or not to switch to autonomous follow-up running control due to communication interruption during communication follow-up running control may be applied during acceleration.

That is, the radar recognition delay τ _sensor that is the detection delay time is the time from when the acceleration control of the preceding vehicle 100 is started until the host vehicle 1 detects the start of the acceleration control of the preceding vehicle 100 as travel information. The actuator response delay τ _act which is the control response delay time may be a time from when the own vehicle 1 transmits the acceleration control signal until the own vehicle 1 starts the acceleration control. In this case, the actuator corresponds to the engine 5 or the motor. As in deceleration during communication follow-up running control, the set inter-vehicle time τ _set is set to be equal to or greater than the sum of the radar recognition delay τ _sensor and the actuator response delay τ _act . At least one of the radar recognition delay τ _{sensor and the} actuator response delay τ _act is changed according to the environment and the driving situation.

In this case, the traveling state of the host vehicle 1 is based on the generation form of the driving force when the host vehicle 1 is accelerated, and the driving force is only the engine 5 or only the motor, or the engine 5 and the motor are used in combination. The radar recognition delay τ _sensor or the like may be changed according to the generation form of these driving forces. When generating the driving force, the response characteristics to the acceleration instruction are different between the engine 5 and the motor. Thus, by changing the radar recognition delay τ _sensor or the like according to the driving force generation mode, The inter-vehicle distance control during the follow-up running can be appropriately controlled including during acceleration.

Further, when the vehicle 1 is such a hybrid vehicle, not only a normal hydraulic brake but also a so-called regenerative brake that generates power using energy during deceleration may be used. When the regenerative brake can be used, the generation state of the braking force when the host vehicle 1 is decelerating as the traveling state of the host vehicle 1 used when changing the radar recognition delay τ _sensor or the actuator response delay τ _act May be used. That is, the radar recognition delay τ _sensor or the like may be changed according to the ratio between the braking force generated by the hydraulic brake when the host vehicle 1 is decelerated and the braking force generated by the regenerative brake. When generating the braking force, the response characteristics to the instruction to start braking are different between the hydraulic brake and the regenerative brake, and thus the radar recognition delay τ _sensor etc. is changed using the braking force generation form, by setting the set inter-vehicle time tau _{the set} on the basis of these, it is possible to set inter-vehicle time tau _{the set,} to the inter-vehicle time suitable to the running conditions. As a result, inter-vehicle distance control during follow-up traveling can be performed more appropriately.

  Moreover, since each numerical value in the vehicle control device 2 according to the above-described embodiment shows an example of the vehicle control device 2 or the following traveling control, each numerical value in the vehicle control device 2 or the following traveling control is It is not restricted to what was mentioned above.

  In the vehicle control device 2 according to the above-described embodiment, when the follow-up traveling control to the preceding vehicle 100 is performed, the deceleration of the own vehicle 1 when the preceding vehicle 100 decelerates until the inter-vehicle time elapses. The vehicle 1 is controlled so as to have a deceleration having the same magnitude as the deceleration of the preceding vehicle 100. However, the vehicle 1 may be equipped with another device to perform the deceleration control. For example, in addition to the vehicle control device 2 according to the embodiment, the vehicle 1 is a device that warns the driver or applies a brake when the vehicle 1 is likely to collide with the preceding vehicle 100 during normal traveling. A crash safety (PCS) device may be provided. In this case, apart from the communication follow-up running control ECU 40 and the autonomous follow-up running control ECU 60, a PCSECU (not shown) is provided as a PCS control unit that performs PCS control, and the PCSECU determines that the PCS control is performed based on the detection result of the radar 12. In that case, the brake hydraulic pressure control device 8 is controlled to cause the own vehicle 1 to generate a deceleration. Thereby, even at the time of PCS control, the possibility of occurrence of a rear-end collision with the preceding vehicle 100 can be reduced as much as possible.

  In other words, the vehicle control device 2 according to the embodiment actively acquires travel information of the preceding vehicle 100 and appropriately decelerates so that the deceleration of the host vehicle 1 does not become too large according to the deceleration of the preceding vehicle 100. However, in the PCS device, when there is a possibility that a rear-end collision with the preceding vehicle 100 may occur, the host vehicle 1 is decelerated so as to reduce this possibility. Thus, by providing the vehicle control device 2 and the PCS device according to the embodiment, it is possible to perform different deceleration control depending on the situation at the time of traveling, and more appropriately perform the deceleration according to the traveling condition. it can. Further, by providing the PCS device in this way, it is possible to reduce the possibility of a rear-end collision with the preceding vehicle 100 by the PCS device not only during follow-up running but also during normal running without follow-up running. .

  Further, the PCS control by the PCS device may be performed in combination with the follow-up running control. When the preceding vehicle 100 is normally decelerated during the follow-up running control, the vehicle control device 2 performs the deceleration control so that the preceding vehicle 100 becomes abrupt. If it is likely that the vehicle will collide with the preceding vehicle 100 due to deceleration, the PCS device may perform deceleration control. As a result, the possibility of a rear-end collision with the preceding vehicle 100 in the follow-up traveling control can be more reliably reduced.

  As described above, the vehicle control device according to the present invention is useful for a vehicle that performs follow-up control of a preceding vehicle, and is particularly suitable for performing inter-vehicle communication with a preceding vehicle.

1 Vehicle (own vehicle)
2 Vehicle control device 12 Radar 15 Inter-vehicle communication device 20 Travel control ECU
DESCRIPTION OF SYMBOLS 22 Brake control part 28 Travel mode switching part 30 Inter-vehicle time detection part 33 Deceleration calculation part 34 Relative speed calculation part 35 Deceleration relative speed calculation part 38 Inter-vehicle time setting part 40 Communication follow-up travel control ECU
41 Inter-vehicle distance setting unit 45 Leading vehicle travel information acquisition unit 46 Leading vehicle maximum deceleration derivation unit 51 Communication interruption determination unit 60 Autonomous tracking travel control ECU
61 Forward state acquisition unit 62 Inter-vehicle distance setting unit 63 Leading vehicle deceleration derivation unit 100 Leading vehicle

Claims (5)

A vehicle control device that acquires travel information of a preceding vehicle that travels in front of the traveling direction of the host vehicle and performs follow-up travel control that follows the preceding vehicle based on the acquired travel information,
A forward situation detecting means for detecting the traveling information of the preceding vehicle using a detection wave;
As the following traveling control, it is possible to perform communication following traveling control for controlling the traveling state of the own vehicle based on the traveling information of the preceding vehicle acquired by inter-vehicle communication.
At the time of the follow-up traveling control, a detection delay time from when the acceleration / deceleration control of the preceding vehicle starts until the host vehicle detects the start of the acceleration / deceleration control of the preceding vehicle as the traveling information;
A control response delay time from when the host vehicle transmits the acceleration / deceleration control signal until the host vehicle starts acceleration / deceleration control; and
A detection time or a control response delay time according to at least one of an environment or a driving situation when the host vehicle travels, and a time interval between the preceding vehicle and the host vehicle is set. Change at least one of the
When the follow-up running control is performed by the communication follow-up running control, a communication interruption determination time is set, and after the detection of the traveling information of the preceding vehicle by the front situation detection means, the communication interruption determination time If the communication with the preceding vehicle is not restored, the acceleration / deceleration control signal is transmitted .   The vehicle control device according to claim 1, wherein the environment during travel of the host vehicle is a temperature around the host vehicle.   The vehicle control apparatus according to claim 1, wherein the traveling state is a form of detection means used for acquiring the traveling information.   The vehicle control apparatus according to claim 1, wherein the traveling state is a generation form of a driving force during acceleration of the host vehicle.   The vehicle control apparatus according to claim 1, wherein the traveling state is a generation form of a braking force when the host vehicle is decelerated.

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