Patents by Inventor Masaki Shiota
Masaki Shiota has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
-
Patent number: 11529994Abstract: A vehicle control system installed on a vehicle includes: an automatic steering control device configured to execute automatic steering control that determines a steering angle command value and controls steering of the vehicle such that an actual steering angle follows the steering angle command value; a stop state detection device configured to detect a stop state where the vehicle is stopped; and an override detection device configured to detect an override operation by a driver of the vehicle. When the override operation is detected in the stop state, the automatic steering control device prohibits variation in the actual steering angle due to the automatic steering control, until the vehicle starts moving.Type: GrantFiled: February 26, 2019Date of Patent: December 20, 2022Assignee: TOYOTA JIDOSHA KABUSHIKI KAISHAInventors: Ryo Irie, Masaki Shiota
-
Patent number: 11524706Abstract: An override conciliating portion executes processing to conciliate an override request during an execution of automated driving control (i.e., override conciliation processing). In the override conciliation processing, it is determined whether or not there is the override request (step S20). If the determination result of the step S20 is positive, it is determined whether or not a second automated driving mode is selected as an operation mode (step S21). If the determination result of the step S21 is negative, acceptance processing of the override request is executed (step S22). If the determination result of the step S21 is positive, invalidation processing of the override request is executed (step S23).Type: GrantFiled: April 6, 2020Date of Patent: December 13, 2022Assignee: TOYOTA JIDOSHA KABUSHIKI KAISHAInventors: Yoji Kunihiro, Takahiro Kojo, Shun Mizoo, Takahiro Yokota, Shunsuke Tanimori, Hisaya Akatsuka, Masaki Shiota, Hirotaka Tokoro
-
Publication number: 20220389514Abstract: Provided is a means for predicting a therapeutic effect of BCG intravesical infusion therapy in treating bladder cancer, in particular, resistance to BCG intravesical infusion therapy in treating bladder cancer and/or possibility of relapse after BCG intravesical infusion therapy in treating bladder cancer. The method for predicting a therapeutic effect of BCG intravesical infusion therapy in treating bladder cancer comprises: a step of detecting presence or absence of two or more single nucleotide polymorphisms (SNPs), wherein the method comprises predicting resistance to BCG intravesical infusion therapy in treating bladder cancer and/or predicting possibility of relapse after BCG intravesical infusion therapy in treating bladder cancer.Type: ApplicationFiled: September 30, 2020Publication date: December 8, 2022Inventors: Masaki SHIOTA, Masatoshi ETO
-
Publication number: 20210177010Abstract: A pet food is provided, including a base substance and a coating part that coats a part of the base substance, in which a part of the base substance is exposed and a component composition of the base substance and a component composition of the coating part are different from each other.Type: ApplicationFiled: June 25, 2018Publication date: June 17, 2021Applicant: Unicharm CorporationInventors: Thi Yen Minh Nguyen, Munehiro Usui, Waka Sawada, Masaki Shiota, Tadatoshi Nobata
-
Patent number: 10946843Abstract: A vehicle travel assistance system includes distributing half of target yawing moment to inner wheels and distributing the rest to outer wheels; increasing the amount of increase in the braking force of the inner wheels as the target yawing moment distributed to the inner wheels increases, and increasing the amount of decrease in the braking force of the outer wheels as the target yawing moment distributed to the outer wheels increases; and causing the braking force of the inner wheels to increase according to the amount of increase in the braking force of the inner wheels, and causing the braking force of the outer wheels to decrease according to the amount of decrease in the braking force of the outer wheels.Type: GrantFiled: September 29, 2016Date of Patent: March 16, 2021Assignee: ADVICS CO., LTD.Inventors: Yosuke Ohmori, Masaki Shiota, Yosuke Yamada, Yukio Mori
-
Patent number: 10919569Abstract: A vehicle control system installed on a vehicle executes turning control that controls a turning device configured to turn a wheel of the vehicle. The turning control includes: first turning control that generates a target trajectory and makes the vehicle follow the target trajectory; and second turning control that is executed independently of the first turning control without depending on the target trajectory. When the first turning control and the second turning control are executed simultaneously, the vehicle control system determines whether the first turning control counteracts turning by the second turning control. When the first turning control counteracts the turning by the second turning control, the vehicle control system replans the target trajectory by designating at least one of a current position and a current yaw angle of the vehicle as a starting point of the target trajectory.Type: GrantFiled: July 8, 2019Date of Patent: February 16, 2021Assignee: TOYOTA JIDOSHA KABUSHIKI KAISHAInventors: Go Inoue, Masaki Shiota, Hirotaka Tokoro
-
Publication number: 20200324792Abstract: An override conciliating portion executes processing to conciliate an override request during an execution of automated driving control (i.e., override conciliation processing). In the override conciliation processing, it is determined whether or not there is the override request (step S20). If the determination result of the step S20 is positive, it is determined whether or not a second automated driving mode is selected as an operation mode (step S21). If the determination result of the step S21 is negative, acceptance processing of the override request is executed (step S22). If the determination result of the step S21 is positive, invalidation processing of the override request is executed (step S23).Type: ApplicationFiled: April 6, 2020Publication date: October 15, 2020Inventors: Yoji Kunihiro, Takahiro Kojo, Shun Mizoo, Takahiro Yokota, Shunsuke Tanimori, Hisaya Akatsuka, Masaki Shiota, Hirotaka Tokoro
-
Publication number: 20200178568Abstract: There is provided a method of producing pet food including a base substance and a coating part that coats a part of the base substance, the method including: (a) a step of processing a coating part forming composition having a composition different from that of the base substance, at a first temperature (T1); (b) a step of processing the coating part forming composition at a second temperature (T2), after the step (a); (c) a step of processing the coating part forming composition at a third temperature (T3), after the step (b); (d) a step of coating a part of the base substance with the coating part forming composition obtained in the step (c); and (e) a step of solidifying the coating part forming composition with which the part of the base substance is coated, in which there is a relationship of the first temperature (T1)>the third temperature (T3)>the second temperature (T2).Type: ApplicationFiled: December 4, 2019Publication date: June 11, 2020Applicant: Unicharm CorporationInventors: Masaki Shiota, Munehiro Usui, Hidetaka Oyama, Hayato Nishitani
-
Publication number: 20200070875Abstract: A vehicle control system installed on a vehicle executes turning control that controls a turning device configured to turn a wheel of the vehicle. The turning control includes: first turning control that generates a target trajectory and makes the vehicle follow the target trajectory; and second turning control that is executed independently of the first turning control without depending on the target trajectory. When the first turning control and the second turning control are executed simultaneously, the vehicle control system determines whether the first turning control counteracts turning by the second turning control. When the first turning control counteracts the turning by the second turning control, the vehicle control system replans the target trajectory by designating at least one of a current position and a current yaw angle of the vehicle as a starting point of the target trajectory.Type: ApplicationFiled: July 8, 2019Publication date: March 5, 2020Applicant: TOYOTA JIDOSHA KABUSHIKI KAISHAInventors: Go INOUE, Masaki SHIOTA, Hirotaka TOKORO
-
Patent number: 10562528Abstract: A vehicle travel assist device which enables setting of a target travel route while limiting the increase in computational load including an automatic drive control device is provided with: a storage unit that stores a map indicating the relation between a limit value of variation in lateral acceleration and time; a profile creation unit that, when information specifying a target position is inputted, creates a lateral acceleration profile indicating the relation between the lateral acceleration of a vehicle and time on the basis of the target position, an estimated time of arrival, and the map stored in the storage unit; and a target deriving unit that derives a target travel route leading to the target position by performing integration twice on the created lateral acceleration profile.Type: GrantFiled: September 29, 2016Date of Patent: February 18, 2020Assignee: ADVICS CO., LTD.Inventors: Masaki Shiota, Yosuke Ohmori, Yukio Mori, Yosuke Yamada
-
Publication number: 20190315403Abstract: A vehicle control system installed on a vehicle includes: an automatic steering control device configured to execute automatic steering control that determines a steering angle command value and controls steering of the vehicle such that an actual steering angle follows the steering angle command value; a stop state detection device configured to detect a stop state where the vehicle is stopped; and an override detection device configured to detect an override operation by a driver of the vehicle. When the override operation is detected in the stop state, the automatic steering control device prohibits variation in the actual steering angle due to the automatic steering control, until the vehicle starts moving.Type: ApplicationFiled: February 26, 2019Publication date: October 17, 2019Applicant: TOYOTA JIDOSHA KABUSHIKI KAISHAInventors: Ryo Irie, Masaki Shiota
-
Publication number: 20180281787Abstract: A vehicle travel assist device which enables setting of a target travel route while limiting the increase in computational load including an automatic drive control device is provided with: a storage unit that stores a map indicating the relation between a limit value of variation in lateral acceleration and time; a profile creation unit that, when information specifying a target position is inputted, creates a lateral acceleration profile indicating the relation between the lateral acceleration of a vehicle and time on the basis of the target position, an estimated time of arrival, and the map stored in the storage unit; and a target deriving unit that derives a target travel route leading to the target position by performing integration twice on the created lateral acceleration profile.Type: ApplicationFiled: September 29, 2016Publication date: October 4, 2018Applicant: ADVICS CO., LTD.Inventors: Masaki SHIOTA, Yosuke OHMORI, Yukio MORI, Yosuke YAMADA
-
Publication number: 20180281763Abstract: A vehicle travel assistance system includes distributing half of target yawing moment to inner wheels and distributing the rest to outer wheels; increasing the amount of increase in the braking force of the inner wheels as the target yawing moment distributed to the inner wheels increases, and increasing the amount of decrease in the braking force of the outer wheels as the target yawing moment distributed to the outer wheels increases; and causing the braking force of the inner wheels to increase according to the amount of increase in the braking force of the inner wheels, and causing the braking force of the outer wheels to decrease according to the amount of decrease in the braking force of the outer wheels.Type: ApplicationFiled: September 29, 2016Publication date: October 4, 2018Applicant: ADVICS CO., LTD.Inventors: Yosuke OHMORI, Masaki SHIOTA, Yosuke YAMADA, Yukio MORI
-
Patent number: 9365215Abstract: A collision avoidance ECU sets a model deceleration change amount to smaller value in a state in which it is difficult to reduce the speed of a host vehicle than in a state in which it is easy to reduce the speed of the host vehicle. The collision avoidance ECU calculates a first target value by multiplying the model deceleration change amount by the elapsed time. The collision avoidance ECU obtains a subtraction value by subtracting the current reference relative deceleration from the first target value. Then, the collision avoidance ECU determines a target relative deceleration to be a greater value when the subtraction value is large than when the subtraction value is small, and carries out brake control so that the reference relative deceleration approaches the target relative deceleration.Type: GrantFiled: June 13, 2013Date of Patent: June 14, 2016Assignee: ADVICS CO., LTD.Inventors: Yosuke Ohmori, Masaki Shiota, Masayoshi Takeda, Yukio Mori
-
Patent number: 9298187Abstract: A collision avoidance ECU sets a target relative deceleration to a first target value when a brake control starting condition is satisfied, and carries out a first brake control for bringing a relative deceleration closer to the target relative deceleration. When a reference relative deceleration with reference to the relative deceleration at a first point in time has reached a specified relative deceleration, the collision avoidance ECU determines a greater value for a second target value when the amount of change in deceleration, which is the amount of change in the reference relative deceleration at the point in time, is small than when the amount of change in deceleration is large. The collision avoidance ECU then sets the target relative deceleration to the second target value, and carries out a second brake control for bringing the relative deceleration closer to the target relative deceleration.Type: GrantFiled: June 13, 2013Date of Patent: March 29, 2016Assignee: ADVICS CO., LTD.Inventors: Masaki Shiota, Yosuke Ohmori, Yukio Mori, Masayoshi Takeda
-
Patent number: 9238464Abstract: An ECU calculates: a free running distance, which is a distance that a vehicle can travel from a first time point at which a speed-reduction control is started to a second time point at which the relative deceleration begins to increase by the start of the speed-reduction control; an increase travel distance, which is a distance that the vehicle can travel from the second time point to a third time point at which the relative deceleration reaches the target relative deceleration; and a post-completion travel distance, which is a distance that the vehicle can travel from the third time point to a time point at which the relative speed is made equal to or less than the specified speed. The ECU obtains a speed reduction distance based on a result of adding up the free running distance, the increase travel distance, and the post-completion travel distance.Type: GrantFiled: June 13, 2013Date of Patent: January 19, 2016Assignee: ADVICS CO., LTD.Inventors: Yosuke Ohmori, Yukio Mori, Masaki Shiota, Masayoshi Takeda
-
Publication number: 20150314784Abstract: A collision avoidance ECU sets a model deceleration change amount to smaller value in a state in which it is difficult to reduce the speed of a host vehicle than in a state in which it is easy to reduce the speed of the host vehicle. The collision avoidance ECU calculates a first target value by multiplying the model deceleration change amount by the elapsed time. The collision avoidance ECU obtains a subtraction value by subtracting the current reference relative deceleration from the first target value. Then, the collision avoidance ECU determines a target relative deceleration to be a greater value when the subtraction value is large than when the subtraction value is small, and carries out brake control so that the reference relative deceleration approaches the target relative deceleration.Type: ApplicationFiled: June 13, 2013Publication date: November 5, 2015Applicant: ADVICS CO., LTD.Inventors: Yosuke OHMORI, Masaki SHIOTA, Masayoshi TAKEDA, Yukio MORI
-
Publication number: 20150151755Abstract: An ECU calculates: a free running distance, which is a distance that a vehicle can travel from a first time point at which a speed-reduction control is started to a second time point at which the relative deceleration begins to increase by the start of the speed-reduction control; an increase travel distance, which is a distance that the vehicle can travel from the second time point to a third time point at which the relative deceleration reaches the target relative deceleration; and a post-completion travel distance, which is a distance that the vehicle can travel from the third time point to a time point at which the relative speed is made equal to or less than the specified speed. The ECU obtains a speed reduction distance based on a result of adding up the free running distance, the increase travel distance, and the post-completion travel distance.Type: ApplicationFiled: June 13, 2013Publication date: June 4, 2015Inventors: Yosuke Ohmori, Yukio Mori, Masaki Shiota, Masayoshi Takeda
-
Publication number: 20150153737Abstract: A collision avoidance ECU sets a target relative deceleration to a first target value when a brake control starting condition is satisfied, and carries out a first brake control for bringing a relative deceleration closer to the target relative deceleration. When a reference relative deceleration with reference to the relative deceleration at a first point in time has reached a specified relative deceleration, the collision avoidance ECU determines a greater value for a second target value when the amount of change in deceleration, which is the amount of change in the reference relative deceleration at the point in time, is small than when the amount of change in deceleration is large. The collision avoidance ECU then sets the target relative deceleration to the second target value, and carries out a second brake control for bringing the relative deceleration closer to the target relative deceleration.Type: ApplicationFiled: June 13, 2013Publication date: June 4, 2015Applicant: ADVICS CO., LTD.Inventors: Masaki Shiota, Yosuke Ohmori, Yukio Mori, Masayoshi Takeda
-
Patent number: D928448Type: GrantFiled: November 15, 2019Date of Patent: August 24, 2021Assignee: Unicharm CorporationInventors: Masaki Shiota, Munehiro Usui, Waka Sawada, Thi Yen Minh Nguyen, Hayato Nishitani