Patent application number | Description | Published |
20110035126 | DRIVING FORCE CONTROLLING APPARATUS OF VEHICLE - A driving force controlling apparatus includes a driving force controller configured to determine a state of a road surface. A driving force controller is configured to control a driving force of a vehicle based on the road surface state. A rear-wheel speed sensor is configured to detect a rear-wheel speed. A low-friction-coefficient road surface determining device is configured to determine whether the road surface is a low-friction-coefficient road surface using the rear-wheel speed on a predetermined condition. A determination prohibition device is configured to prohibit the low-friction-coefficient road surface determining device from determining whether the road surface is a low-friction-coefficient road surface, if (a) the rear-wheel speed sensor is abnormal, or if (b) a predetermined time has elapsed from when a shift range is changed from a reverse range to a drive range and/or (c) a gear position has become greater than or equal to a predetermined gear position. | 02-10-2011 |
20110035127 | VEHICLE TRANSMISSION CONTROL APPARATUS - A vehicle transmission control apparatus includes an expected-acceleration calculator configured to calculate an expected acceleration of a vehicle based on at least an engine load and a vehicle speed. An actual-acceleration calculator is configured to calculate an actual acceleration of the vehicle. An uphill determination device is configured to calculate an uphill determination value based on a difference between the expected acceleration and the actual acceleration and configured to calculate a corrected uphill determination value by subjecting the uphill determination value to moderating calculation using a moderating coefficient and to update the corrected uphill determination value in accordance with the moderating coefficient. A transmission-characteristic selecting device is configured to select one of transmission characteristics based on the corrected uphill determination value. A transmission controller is configured to perform transmission control based on the transmission characteristic selected by the transmission-characteristic selecting device. | 02-10-2011 |
20130261913 | SAFETY CONTROL APPARATUS FOR AUTOMATIC TRANSMISSION AND METHOD FOR CONTROLLING AUTOMATIC TRANSMISSION - A safety control apparatus for an automatic transmission includes a speed range detector, an oil temperature detector, a vehicle speed detector, a speed-range shifting device, a shift inhibiting device, and a maximum-speed limiting device. The shift inhibiting device is configured to inhibit an automatic downshift and a manual downshift by a driver if the speed-range shifting device performs a forcible upshift. The maximum-speed limiting device is configured to limit a maximum vehicle speed to a third vehicle speed if an oil temperature reaches a second oil temperature which is higher than a first oil temperature and if a vehicle speed is not lower than a second vehicle speed which is higher than a first vehicle speed. | 10-03-2013 |
20140256508 | AUTOMATIC TRANSMISSION AND METHOD FOR CONTROLLING THE SAME - An automatic transmission includes an input member, a planetary gear set, a plurality of engagement mechanisms, an output member, a switching mechanism, an engine braking determination device, a vehicle speed detector, and a controller. The controller is configured to prevent the switching mechanism from switching a mode from a fixed mode to a reverse rotation prevention mode when a shift position is changed from a reverse drive range to a forward drive range, and if the engine braking determination device determines that a vehicle is in an engine braking mode or if a travel speed of the vehicle detected by the vehicle speed detector is higher than a predetermined speed. | 09-11-2014 |
20140303860 | AUTOMATIC TRANSMISSION - An automatic transmission includes an input member, a planetary gear set, a plurality of engagement mechanisms, an output member, a shift position detecting unit, an input rotational speed detecting unit, a control unit, and a switching mechanism. When a shift position is changed from a forward drive range to a reverse drive range, the control unit performs a reverse preparation mode in which a rotational speed of an element to be fixed by the switching mechanism is lower than or equal to a predetermined speed by setting an engagement mechanism in one of a connection mode and a fixed mode. Upon performing the reverse preparation mode, the control unit engages the engagement mechanism that connects the element fixed by the switching mechanism to the input member and, thereafter, engages the engagement mechanism that makes the rotational speed of the input member lower than or equal to the predetermined speed. | 10-09-2014 |
20140350808 | AUTOMATIC TRANSMISSION - An automatic transmission includes an input member, a planetary gear mechanism, a plurality of engagement mechanisms, an output member, a shift position detector, an input rotational speed detector, a controller, and a switching mechanism. The controller is configured to set the switching mechanism in a reverse-rotation prevention state when a shift position is set in a forward movement range and configured to set the switching mechanism in a fixed state when the shift position is set in a backward movement range. The controller is configured to control the plurality of engagement mechanisms so that the input member is capable of rotating and rotation of the output member is prevented in a case in which a vehicle is moving backward, the shift position is switched from the backward movement range to the forward movement range, and a vehicle speed is greater than or equal to a first predetermined speed. | 11-27-2014 |
20140364267 | AUTOMATIC TRANSMISSION CONTROLLER - An automatic transmission controller for controlling an automatic transmission includes a neutral controller which is configured to perform neutral control, a neutral control permission determiner, and an engagement controller. The automatic transmission includes a plurality of planetary gear mechanisms and a plurality of engagement mechanisms. One of the plurality of engagement mechanisms is a mechanical engagement mechanism. The engagement controller is configured to allow rotation of an input shaft of the automatic transmission in a case where the neutral control determiner permits the neutral control and configured to set the plurality of engagement mechanisms including at least the mechanical engagement mechanism so as to fix an output shaft of the automatic transmission to a casing of the automatic transmission in a case where the output shaft of the automatic transmission is rotated by a wheel of a vehicle in a rotational direction such that the vehicle moves backward. | 12-11-2014 |
20140364276 | AUTOMATIC TRANSMISSION CONTROLLER - An automatic transmission controller for controlling an automatic transmission includes an idling reduction controller, an idling-reduction-control permission determiner, and an engagement controller. The idling-reduction-control permission determiner is configured to determine whether or not to permit an idling reduction control. The engagement controller, in a case where the idling-reduction-control permission determiner permits the idling reduction control, is configured to allow rotation of an input shaft of an automatic transmission, and in a case where an output shaft of the automatic transmission is rotated by a wheel of a vehicle in a rotational direction such that the vehicle moves backward, is configured to set a plurality of engagement mechanisms including at least a mechanical engagement mechanism so as to fix the output shaft of the automatic transmission to a casing of the automatic transmission or so as to prevent the vehicle from moving backward. | 12-11-2014 |
Patent application number | Description | Published |
20100126816 | HYDRAULIC CONTROL DEVICE FOR TORQUE CONVERTER WITH LOCK-UP CLUTCH - A control section determines a driving state of a vehicle and controls first and second solenoid valves on the basis of the determined driving state. An oil passage length of a second oil discharge passage is shorter than that of a first oil discharge passage and a discharge end of the second oil discharge passage is opened at a lower position than that of the first oil discharge passage. The control section derives hydraulic oil, discharged from an oil chamber via a first shift valve, to the first oil discharge passage by means of a second shift valve when it is determined that the driving state is one during normal driving. The control section derives the hydraulic oil to the second oil discharge passage by means of the second shift valve when it is determined that the driving state is one required for rapid lock-up off. | 05-27-2010 |
20100191434 | DRIVING-FORCE CONTROL APPARATUS FOR VEHICLE - Several low-friction-coefficient road-surface determination devices determine whether a road surface has a low friction coefficient based on the highest and lowest wheel speeds; the wheel speeds of front and rear wheels; wheel speeds of a left-hand and right-hand driving wheels; and by comparing a reference vehicle-body acceleration calculated from a driving force of an engine with an actual vehicle-body acceleration calculated from a calculated number of revolutions of differential gears. A low-friction-coefficient road-surface total-determination device makes a total determination as to whether the road surface has a low friction coefficient based on the determination results of the low-friction-coefficient road-surface determination devices. Accordingly, each low-friction-coefficient road-surface determination device is capable of compensating for disadvantages of the other devices. | 07-29-2010 |
20130179044 | CONTROL APPARATUS FOR VEHICLE AUTOMATIC TRANSMISSION - A sport running estimated value LEVELSP obtained by searching a value on a map prepared in advance based on an average values AGYAVE of lateral accelerations GY of a vehicle and on average values of vehicle speed changes is calculated, and a vehicle speed on a shift map is searched based on the sport running estimated value LEVELSP and an estimated value DA of a vehicle gradient, whereby a downshift vehicle speed VA at which a downshift is implemented is calculated. Then, the downshift is implemented in a case where actuation of a brake is detected, deceleration of the vehicle is a predetermined value or more, and a current vehicle speed is a downshift vehicle speed VA or more. In such a way, running on a meandering road, for which the downshift and a subsequent shift hold should be implemented, is sensed appropriately. | 07-11-2013 |
20130184949 | CONTROL DEVICE FOR AUTOMATIC TRANSMISSION - For each engine operation state to which a variable cylinder engine can be switched, a fuel consumption amount to be consumed to generate a driving force required to maintain a current traveling state of a vehicle for each of a current gear and a new gear after a possible shift-up is calculated. An automatic shift control of shifting up to the new gear is performed in a condition that a calculated fuel consumption amount of the new gear after the possible shift-up is smaller than a calculated fuel consumption amount of the current gear. In this way, the fuel consumption amount can be optimally reduced and the shift control can be performed without degrading the traveling performance, even in the vehicle equipped with the variable cylinder engine. | 07-18-2013 |
20140190784 | PARKING LOCK DEVICE FOR TRANSMISSION - In case of power supply loss, a parking lock is operated by moving a piston of a hydraulic actuator rightward by use of hydraulic pressure accumulated in an accumulator. If a hydraulic pressure generating source becomes unable to generate line pressure due to its failure after the power supply loss, it is desirable that the parking lock be releasable to tow a vehicle, for example. In that time, because the hydraulic pressure in the accumulator has got out via an orifice, the parking lock can be released by moving the piston in the hydraulic actuator leftward by use of a manual operation device without interruption by the hydraulic pressure accumulated in the accumulator. Because the hydraulic pressure in the accumulator is automatically released via the orifice, a complicated mechanism for enabling the manual operation device to work without interference from the hydraulic actuator becomes unnecessary. | 07-10-2014 |
Patent application number | Description | Published |
20100262351 | ENGINE CONTROL SYSTEM AND METHOD FOR CONTROLLING ENGINE AIR FLOW DURING DECELERATION FUEL CUT - An engine control system and method for controlling engine air flow during a deceleration fuel cut includes an internal combustion engine, an anti-lock braking system (ABS), and an electronic control unit (ECU) that controls the engine. The ECU establishes a desired air flow rate for the internal combustion engine, which is taken from an ABS failed condition look-up table when determined that the ABS has failed while the engine is in a deceleration fuel cut mode, and otherwise is taken from a normal condition look-up table. | 10-14-2010 |
20110276239 | Torque Compensation Method And System - A system and method of compensating for torque converter slip in a motor vehicle include measuring rotational speeds of an engine crankshaft and mainshaft, as well as measuring operating temperatures of a fluid associated with the motor vehicle. Engine output torque is adjusted as required by controlling some combination of ignition timing, intake air flow, fuel injection, and accessory load. | 11-10-2011 |
20140195130 | Torque Compensation Method and System - A system and method of compensating for torque converter slip in a motor vehicle include measuring rotational speeds of an engine crankshaft and mainshaft, as well as measuring operating temperatures of a fluid associated with the motor vehicle. Engine output torque is adjusted as required by controlling some combination of ignition timing, intake air flow, fuel injection, and accessory load. A system and method for deactivating a torque compensation system retrieves a number of times the torque compensation system has been activated over a set period. If the number exceeds a predetermined number of activations, the torque compensation system is deactivated. | 07-10-2014 |