An image processing apparatus 10 includes an output unit 14 and a processor 16. The output unit 14 outputs to a movable object 12 information indicating an action to be performed by the movable object 12. The processor 16 determines a first action of the movable object 12 based on a state of a target, the state being sensed in imagery of a region around the movable object 12. The processor 16 causes the output unit 14 to output information indicating the first action. The processor 16 determines a second action of the movable object 12 based on a state of the target, the state being sensed in imagery of the region around the movable object 12, the imagery being captured after the first action of the movable object 12. The processor 16 causes the output unit 14 to output information indicating the second action at a time depending on a speed of a predetermined motion of the target. The predetermined motion of the target is a motion that the target makes before the first action is determined or after the first action of the movable object 12.

Methods, systems, and apparatus for a monitoring system are disclosed. The monitoring system includes a memory configured to store image data and a first camera configured to capture first image data including the activity of a passenger within the vehicle. The electronic control unit is configured to obtain, from the first camera, the first image data including the passenger, determine an activity of the passenger based on the first image data, and determine that the activity of the passenger will be different than a baseline activity of the passenger. The electronic control unit is configured to record and capture, in the memory and using the camera, the first image data for a time period before and after the determination that the activity of the passenger will be different than the baseline activity.

A vehicle may include: a display provided inside the vehicle; and a controller configured to control the display, based on a condition being satisfied, to display a vehicle image comprising a graphic object and a plurality of indicators, wherein the graphic object indicates a plurality of portions of the vehicle image, and wherein each of the plurality of indicators is respectively associated with one of the plurality of portions. Based on a user utterance associated with at least one indicator of the plurality of indicators, the controller may be configured to control a control target corresponding to the at least one indicator.

A vehicle may include: a display provided inside the vehicle; and a controller configured to control the display, based on a condition being satisfied, to display a vehicle image comprising a graphic object and a plurality of indicators, wherein the graphic object indicates a plurality of portions of the vehicle image, and wherein each of the plurality of indicators is respectively associated with one of the plurality of portions. Based on a user utterance associated with at least one indicator of the plurality of indicators, the controller may be configured to control a control target corresponding to the at least one indicator.

An occupant monitoring system for a vehicle comprises: a first light source to generate first infrared (IR) light illuminating at least part of the body of an occupant of a vehicle, wherein the first light source is time modulated with a duty cycle; an IR reflective surface to reflect second IR light reflected from the body of the occupant; and a first IR camera to receive at least part of the second IR light reflected by the IR reflective surface, wherein the first IR camera is time modulated with the duty cycle of the first light source.

An occupant monitoring system for a vehicle comprises: a first light source to generate first infrared (IR) light illuminating at least part of the body of an occupant of a vehicle, wherein the first light source is time modulated with a duty cycle; an IR reflective surface to reflect second IR light reflected from the body of the occupant; and a first IR camera to receive at least part of the second IR light reflected by the IR reflective surface, wherein the first IR camera is time modulated with the duty cycle of the first light source.

An inductively powered camera device including a housing including a base portion configured to be mounted to an exterior surface of a window of a vehicle, a camera supported by the housing and configured to collect image data, an inductive power pad supported by the housing, the inductive power pad in electrical communication with the camera and configured to provide power to the camera, and an inductive power puck configured to be mounted to an interior surface of the window, the inductive power puck configured to inductively provide power to the inductive power pad through the window of the vehicle.

A system for tracking whether a child has been left in a child's car seat includes a child seat sensing device with s proximity sensor that can sense a child's presence in the car seat. The seat sensing device can communicate with a GPS tracker in the vehicle, which can communicate with a camera onboard the vehicle. The seat sensing device is configured so that if the proximity sensor senses a child's presence in the car seat when the vehicle ignition is off, the seat sensing device will send an alert signal to the GPS tracker. In response to the alert signal, the GPS tracker is configured to cause the camera to send an alert to a user, capture an image of the car seat in the vehicle, and send the image to the user.

A system for tracking whether a child has been left in a child's car seat includes a child seat sensing device with s proximity sensor that can sense a child's presence in the car seat. The seat sensing device can communicate with a GPS tracker in the vehicle, which can communicate with a camera onboard the vehicle. The seat sensing device is configured so that if the proximity sensor senses a child's presence in the car seat when the vehicle ignition is off, the seat sensing device will send an alert signal to the GPS tracker. In response to the alert signal, the GPS tracker is configured to cause the camera to send an alert to a user, capture an image of the car seat in the vehicle, and send the image to the user.

An in-cabin monitoring system includes an electronic mirror provided inside a vehicle cabin, a camera that captures an image of an imaging target inside the vehicle cabin, and a light source that is provided in the electronic mirror and emits light into the vehicle cabin. The light source includes a plurality of light emitting diodes, and at least one light emitting diode of the plurality of light emitting diodes are disposed such that optical axes of the one or more light emitting diodes extend in directions different from a direction of an optical axis of an other light emitting diode of the plurality of light emitting diodes.