A system and a control method can prevent interference between front and rear seats for a vehicle, and allow reclining control and slide control for the front and rear seats to be performed, to control a seat back rearward movement angle of a front seat based on a seat back angle of the front seat, a position of the rear seat, and an interval between the front and rear seats at the time of rearward reclining control for the front seat, control a rearward slide movement distance based on the seat back angle of the front seat at the time of rearward slide control for the front seat, and calculate in advance a likelihood that interference will occur between the front and rear seats so as to stop the control operation at the time of performing a rearward reclining control operation and a rearward slide control operation.

A system for setting a three-dimensional (3D) effect includes a memory seat for transmitting and receiving memory seat information of a driver and a 3D cluster for matching the memory seat information and 3D effect setting information and allowing the driver to set the 3D effect or set a two-dimension (2D) mode.

A vehicle seat operation feedback and control system with a seat and an electronic display screen and a processor configured to receive a signal from the seat corresponding to an inoperable, almost inoperable, or undesired condition and provide feedback on the display screen of the inoperable, almost inoperable, or undesired condition.

A seat with an adjusting mechanism for selectively changing a contour and firmness of the seat. A force/pressure sensor is arranged between the contour of the seat which is in contact with the occupant, and the adjusting mechanism. The force/pressure sensor measures the actual force/pressure with which the occupant presses upon the seat, and which force/pressure is adjustable by the respective adjusting mechanism. A control unit stores a desired force/pressure value for the seat, and controls the adjusting mechanism to drive the actual force/pressure towards the desired force/pressure. The seat also has an operator interface which receives input from an operator. The control unit has a manual mode where the adjusting mechanism is only controlled by the operator interface. The control unit in the automatic mode records the actual value from the force/pressure sensor when the operator adjusts the seat through the interface. The control unit then sets the desired force/pressure to the present value of the force/pressure sensor. Once the operator is finished changing the adjusting mechanism, the control unit continues in automatic mode and performs any changes to the adjusting mechanism to drive the actual force/pressure from the force/pressure sensor for the value of the new desired force/pressure.

An on-board vehicle occupant weighing technology includes a simplified vehicle occupant weighing apparatus based on the discovered horwest effect and weighing moderator. The simplified weighing apparatus utilizes a weighing unit connected to the car seat of the vehicle occupant and a further weighing moderator, which provides convenient weighing of the foot part of the occupant's body by the same weighing unit that is connected to the car seat. The technology employs several methods of the weight measurements provided by different moderator approaches. The technology, methods, and simplified weighing apparatus are employed in on-board vehicle overweight and obesity preventing system wherein a weight trend analyzer provides predicting possibility of the occupant's overweight or obesity in a short predetermined period of time and automatically warning a vehicle occupant and a health care provider of the condition. The technology may also provide an accurate and convenient occupant's weight measurement in the vehicle safety devices such as seat belt and air bag Supplemental Restraint System (SRS system) to improve the Occupant Classification System to prevent possible extra force applied to the occupant's body in case of collision.

A vehicle gesture system includes a processor connected to a transceiver and programmed to detect a wireless device associated with a vehicle feature settings interface for a first vehicle feature. The processor is further programmed to detect the wireless device based on received user input at the vehicle feature settings interface of the first vehicle feature. The processor is further programmed to control a setting for the first vehicle feature based on received data associated with one or more gestures made using the wireless device.

Systems and methods for controlling movement of an active payload support system. In one example, a seat system for a vehicle includes a seat, a support structure coupled to the seat and including an actuator configured to move the seat at a command angle relative to a floor of the vehicle responsive to movement of the vehicle, at least one sensor positioned to detect movement of the vehicle, and a controller configured to receive a signal from the at least one sensor, generate a command signal to instruct the actuator to move the seat relative to a floor of the vehicle, determine whether the command signal will cause the seat to exceed a limit, scale the command signal to conform to movement of the vehicle within the limit, and provide a force command to the actuator to move the seat based on the scaled command signal.

Provided is a child restraint system (CRS) with automated installation that provides automated feedback and control of seat installation angle, belt latching and tightening, and confirmation of correct install. The CRS utilizes sensors to monitor CRS base angle relative to level, confirm correct latching of the CRS to its base and then to the vehicle seat, and confirm tightening of the belts to the required tension to be crashworthy. The stepwise operation and confirmation of the installation procedure may be operated via button(s) or other tactical input, and relayed to the user via electronic visual display and/or audible means. All operations will be overseen and processed by an integrated control system, affording minimal user decision or interface. An intelligent latching device which can be adapted for use with an existing CRS is also provided.

Systems and methods to safely transport passengers are described. The system broadcasts over a network, to at least one forward operating base, (FOB) a request for linkage. The system is located in a vehicle that travels on land and is utilized for bidirectional communication with a first system unit type for detecting the presence of a passenger in the vehicle and a second system unit type for communicating different alert types. The first system unit type includes a first child seat control unit and the second system unit type includes at least one FOB including a first FOB. The system receives and registers the first FOB as being linked and receives an occupant present message from the first child seat. The system identifies a temperature inside the vehicle as exceeding a predetermined threshold and communicates a temperature alert message to the first FOB.

A determination apparatus includes: an receiver receives a distance image including a first region located between a first position and a second position, a second region located between the first position and the second position and located closer to the second position than the first region, a third region set within a predetermined area from an operation unit of a piece of equipment installed in front of the first position and the second position; a detector that, on a basis of the distance image, detects a first physical object of a predetermined size or larger in at least either the first region or the second region and detects a second physical object of a predetermined size or larger in the third region; and a determiner, when, in a case where the first physical object and the second physical object have been detected, the first physical object is included in the first region, determines that an operator of the piece of equipment is present in the first position or, when, in a case where the first physical object and the second physical object have been detected, the first physical object is included in the second region, determines that an operator of the piece of equipment is present in the second position.