In a physical state sharable seat, a sensor is configured to acquire a measurement value specific to a physical state of an occupant seated on the seat body; and a controller connected to the sensor and thereby allowed to acquire the measurement value from the sensor is configured to be capable of communicating with other equipment. The controller includes: an evaluation unit configured to compute an evaluation value on the physical state, based on the measurement value; an evaluation value presentation unit configured to present the evaluation value at a terminal to be used by the occupant; a shared data acquisition unit configured to acquire an other-occupant evaluation value that is an evaluation value on a physical state of another person, acquired either by the evaluation unit or from another physical state sharable seat; and a shared data presentation unit configured to present the other-occupant evaluation value at the terminal.

A radar apparatus includes an antenna configured to radiate a first electromagnetic wave in a first radiation angle range including a first direction and radiates a second electromagnetic wave in a second radiation angle range including a second direction opposite to the first direction, and a circuit configured to detect a target in each of the first direction and the second direction on the basis of a first reflected signal of the first electromagnetic wave and a second reflected signal of the second electromagnetic wave, which are received by the antenna.

A vehicle may receive sensor data captured by a sensor, determine that the sensor data represents an object in the environment, and determine a collision probability associated with a predicted collision between the vehicle and the object. Based at least in part on the collision probability, a position of a headrest of the vehicle may be determined relative to a head of an occupant of the vehicle. The headrest may be adjusted in one or more directions prior to occurrence of the predicted collision to minimize injury to the occupant due to the collision.

The invention concerns a system for controlling a smart vehicle seat (1) having a seat base (1b) and a backrest (1c), the surfaces of which are provided with flat pressure sensors, the pressure sensors being connected to a microcontroller (6) via which an actuator element is controllable via a drive unit (9), whereby the actuator element is adapted to change the surface of the seat base (1b) and/or the backrest (1c). It is the object of the invention to develop the system in a way that it automatically adapts to a sitting posture of a user and adjusts the surface of the seat base and of the backrest in an extremely flexible and exactly way depending on the user's posture. Therefore, the invention proposes, that the actuator element comprises one or more valves via which one or more airbags are controllable. Furthermore the invention proposes to use graphene sensors as pressure sensors and to integrate an artificial intelligence module (7) on the microcontroller (6).

Systems and techniques are described herein for detecting a state of presence of a given object in a vehicle. In aspects, techniques include processing data received over time from various devices in the vehicle to determine a set of accumulated scores. The data includes parameters indicative of a presence or absence of a detected object in the vehicle. Further, the processing may be effective to determine a set of accumulated scores. The techniques further include determining an object-related confidence value representing a likelihood that the detected object is present in the vehicle, based on the set of accumulated scores, and then comparing the object-related confidence value to a predetermined threshold. The comparison is sufficient to detect the presence of the detected object in the vehicle if the object-related confidence value exceeds the predetermined threshold.

A vehicle seat includes: a pressure sensor capable of measuring a pressure distribution on a surface of the vehicle seat; a plurality of actuators provided in the vehicle seat; and a controller that controls vibrations generated by the plurality of actuators based on the pressure distribution output by the pressure sensor.

There is provided a computer implemented method for executing a model, for detecting safety seat events, comprising: receiving a plurality of records, each represents measurements taken by a motion sensor mounted on a child safety seat or a base of a child safety seat installed in a vehicle while the vehicle is static or in motion; executing at least one model to classify each of the plurality of records; detecting an occurrence of a child related event based on outputs of the execution of the at least one model; and activating a protection mechanism by a protection mechanism unit according to the detected occurrence of child related event.

A monitoring system for a vehicle cabin, a vehicle including such a monitoring system and a method for monitoring a vehicle cabin. The monitoring system includes a first sensor unit, a second sensor unit and a control unit. The first sensor unit is configured to generate image data of the vehicle cabin. The second sensor unit is configured to generate non-image data of the vehicle cabin. The control unit is configured to collect the image data and the non-image data and determine based thereon whether an obstacle is in the vehicle cabin. The control unit is further configured to limit an actuation of a subsystem if the obstacle is disruptive for the actuation of the subsystem.

A vehicle seat includes right and left side frames 10, and an elastic member (cushion spring 20) run between the right and left side frames 10. The right and left side frames 10 include side walls 11 disposed opposite to each other in a lateral direction, and flange portions (upper flange portions 12) respectively extending laterally inward from the side walls 11, and the elastic member is attached to the flange portions.

A capacitive sensor arrangement includes a sensing electrode having a capacitance (Cx) which depends on the presence of an object in a detection space; a measurement device connected to the sensing electrode and configured to detect the capacitance (Cx) of the sensing electrode; and a conducting structure, wherein the capacitance (Cx) of the sensing electrode depends on a potential of the conducting structure. In order to obtain a reliable capacitive measurement, the measurement device is connected to a power supply between a first potential (Vs) and a second potential (GND), the measurement device being connected to the second potential exclusively via the structure.