An information processing apparatus is configured to perform remote air conditioning by selecting either one of a first air conditioning mode, which is a mode in which remote air conditioning is performed using an engine of a vehicle, and a second air conditioning mode, which is a mode in which remote air conditioning is performed using electric power stored in a battery of the vehicle, wherein the apparatus is provided with a controller configured to select the second air conditioning mode to start air conditioning, in response to obtaining a request for performing remote air conditioning transmitted from a terminal of a user.

An imaging system connected to an occupant monitoring system includes communications with an apparatus for measuring gas or airborne compound concentrations in a vehicle cabin. The apparatus includes a housing configured as a flow tube in fluid communication with ambient air in the vehicle cabin. A spectrometer is mounted within the housing and subject to ambient air flow through the housing, and the spectrometer is connected to a light source and receives reflected light from the air flow to detect by spectrum analysis the concentration of target gases and/or airborne compounds. The spectrometer identifies spectral changes in the light and reflected light within the ambient air flow. The spectrometer communicates with computerized vehicle control systems, and runs software stored to calculate the concentration of target gases and/or airborne compounds from the spectral changes.

A transport refrigeration system including a method for fault tolerant power management. The system includes a first sensor identified as required for operation of the transport refrigeration system and a second sensor operable as a backup for the first sensor. The system also includes a first power supply operably connected to the first sensor and configured to operate the first sensor and a second power supply operably connected to the second sensor and configured to operate the second sensor. The system further includes a controller operably connected to at least the first power supply as well as the first sensor and the second power supply as well as the second sensor, the controller configured to monitor at least the first power supply and the second power supply, if a fault is detected in the first power supply, operate the transport refrigeration system from the second sensor.

A detection system for a vehicle comprises at least one detection device configured to detect conditions in a passenger compartment of the vehicle and a controller. The controller is in communication with the at least one detection device. The controller is configured to monitor data from the at least one detection device prior to an entry of an occupant. Based on the data from the at least one detection device, the controller is further configured to identify at least one change in the passenger compartment of the vehicle. The at least one change in the passenger compartment indicates at least one of an item left behind in the passenger compartment, damage to the vehicle, and contamination of the vehicle.

A transportation refrigeration system and a CAN ID allocation method for a transportation refrigeration system. The transportation refrigeration system includes: a refrigeration circuit including a compressor, a condenser, and a plurality of evaporators connected in parallel, all of which are connected to form a loop; a plurality of chambers, each of the evaporators being located in one of the chambers to adjust the chamber; a plurality of sensors of the same type, each of the sensors being installed in one of the chambers respectively; and a control unit, after being installed in place and energized, the plurality of sensors send their own identification codes to the control unit, and the control unit allocates a CAN ID to each of the sensors after receiving the identification codes of the sensors, so that the identification code of each sensor is bound to the corresponding CAN ID respectively.

A vehicle occupant safety system includes temperature, ambient, and interior monitoring modules. The temperature monitoring module includes at least one temperature sensor. The temperature monitoring module is configured to detect temperatures in zones within an interior of a vehicle. The ambient temperature sensor is configured to detect an ambient temperature within the interior of the vehicle. The interior monitoring module is configured to: based on the detected temperatures of the zones, determine for the zones at least one of a temperature gradient over time or a temperature gradient over space; determine if the ambient temperature is outside a predetermined range; and in response to the ambient temperature being outside the predetermined range and based on the at least one of a temperature gradient over time or a temperature gradient over space, detecting an occupant in the vehicle and performing a countermeasure to prevent an injury to the occupant.

A thermal management system for a passenger cabin of a hybrid vehicle includes a refrigerant loop in fluid communication with a compressor, a condenser, and a chiller. A main cabin evaporator is in fluid communication with the refrigerant loop. A first valve is configured to regulate refrigerant flow through the main cabin evaporator. A temperature sensor disposed at the main cabin evaporator is configured to output a signal indicative of a main cabin evaporator temperature. An auxiliary evaporator is in fluid communication with the refrigerant loop. A second valve is configured to regulate refrigerant flow through the auxiliary evaporator. A controller is programmed to, in response to the main cabin evaporator temperature being less than a threshold while the main cabin evaporator is operated with the second valve closed, open the second valve to cycle refrigerant through the auxiliary evaporator to increase the main cabin evaporator temperature.

Systems, apparatuses, and methods related to using memory device sensors are described. Some memory system or device types include sensors embedded in their circuitry. For instance, another device can be coupled to a memory device with an embedded sensor. The memory device can transmit a signal representing sensor data generated by the embedded sensor using a sensor output coupled to the other device. A controller coupled to a memory device may determine one or more threshold values of a sensor or sensors embedded in a memory device. The memory device may transmit an indication responsive to one or more sensors detecting a value greater or less than a threshold and may transmit the indication to another device.

The invention relates to an operating device (5) for an automatic climate control (2) of a motor vehicle (1) including a sensor assembly (7) for determining an interior temperature in a passenger cabin (4) of the motor vehicle (1) and including an operating area (8), wherein the sensor assembly (7) comprises a circuit board (11) and a sensor unit (12) disposed on the circuit board (11) with a first temperature sensor (17), and wherein a top side (9) of the operating area (8) faces the passenger cabin (4) in an intended installation position of the operating device (5) on the motor vehicle (1). In addition, the invention relates to an automatic climate control (2) as well as to a motor vehicle (1).

A vehicle thermal management system including a refrigerant circuit, a coolant circuit, a chiller, and a controller is provided. The refrigerant circuit may include an electric air conditioning (eAC) compressor and a pressure sensor. The coolant circuit may include a high-voltage battery. The chiller selectively thermally links the circuits. The controller may be programmed to, responsive to receipt of a sensor signal indicating refrigerant pressure exiting the eAC compressor is greater than a high threshold, output a pressure sensor fault error indicating the pressure sensor is faulty. The system may further include a timer to monitor operational timing of the eAC compressor. The controller may be further programmed to direct the system to operate without monitoring the eAC compressor responsive to the timer indicating the eAC compressor has been off for a time-period less than a time threshold reflective of the eAC compressor not being in an at rest state.