A diagnostic device for a sensor 100 provided in an exhaust passage 11 of an internal combustion engine 10 of a vehicle and detecting nitrogen compounds in exhaust gas, the diagnostic device including an offset diagnosis unit 42 which diagnoses, during deceleration of the vehicle in which the internal combustion engine 10 stops fuel injection, an offset amount of a sensor value of the sensor 100 from a zero point based on the sensor value of the sensor value, and a diagnosis prohibition unit 44 which prohibits the diagnosing of the offset amount when a flow rate of the exhaust gas of the internal combustion engine 10 rapidly increases while the offset amount is diagnosed by the offset diagnosis unit 42.

A system and method for preventing unauthorized modification to engine control software or an engine control system of, for example, a refrigerated transport application is provided. Particularly, the embodiments described herein prevent unauthorized parties from inadvertently or intentionally making changes to the engine control software used for controlling the engine or the engine control system that could, for example, potentially bypass emission strategies implemented in the refrigerated transport application. Accordingly, emission strategies such as, for example, EPA Tier IV not-to-exceed (NTE) regulations can be maintained.

The air-fuel ratio feedback control is performed by using a first correction value which is determined depending on a difference between a detected air-fuel ratio (A/F) of an air-fuel mixture and a target A/F and a second correction value which is determined depending on the property of the fuel. Further, fuel property learning control is carried out to correct the first correction value and the second correction value so that an absolute value of the first correction value is not more than a threshold value, when the absolute value of the first correction value is larger than the threshold value after performing the charging with fuel. A combustion continuing correction value range, which is a range of the second correction value to allow the A/F of the mixture to be included in an A/F range in which combustion can be continued, is stored, and the second correction value is set to a value within the combustion continuing correction value range if the A/F feedback control and the fuel property learning control are interrupted.

A turbocharger controller includes a turbocharger compressor temperature module having a compressor inlet air temperature input, and a turbocharger compressor pressure module including a compressor inlet pressure input and a compressor outlet pressure input. A memory module includes a compressor outlet temperature calibration map and a compressor pressure ratio look-up table. A turbocharger boost pressure ratio control module is operatively connected to the turbocharger compressor temperature module, the turbocharger compressor pressure module, and the memory module. The turbocharger boost pressure ratio control module is configured to selectively compare compressor outlet pressure and compressor inlet pressure with values in the compressor ratio look-up table to determine a turbocharger boost pressure set point establishing a desired compressor outlet temperature.

This invention relates to a control device for internal combustion engine for performing an exhaust recirculation control for controlling an operation condition of an exhaust recirculation device (50,52) according to a target exhaust gas recirculation amount (TRegr) set such that a detected air-fuel ratio (AFd) corresponds to an estimated air-fuel ratio (AFe). When the sign of the ratio (Rtregr) of the change amount of the actual target exhaust gas recirculation amount relative to the change amount of the base exhaust gas recirculation amount setting parameter (Q) used for the setting of the base exhaust gas recirculation amount (Regrb) is different from that of the ratio of the change amount of the referential target exhaust gas recirculation amount relative to the change amount of the base exhaust gas recirculation amount setting parameter, the performance of the learning function to calculate the learned correction value (KGn) on the basis of the instant correction value (KT) for correcting the current target exhaust gas recirculation amount such that the air-fuel ratio deviation (Raf) becomes zero is forbidden.

Provided is a boat engine idling revolution number control device, which includes a control unit (30) for performing control so that an engine revolution number converges to a target revolution number based on a result of detection of an engine state. The control unit includes: a decelerating running determining section (314); and a running-load correction calculating function section (315) for calculating a running-load correction signal for correcting a basic torque rate based on the result of determination by the decelerating running determining section and a shift position state detected by the neutral switch. The running-load correction calculating function section resets the running-load correction signal to zero when detecting, based on a behavior of the engine revolution number after the running-load correction, that the engine revolution number is larger than a threshold value calculated based on the target revolution number and the engine revolution number increases.

A system and method for preventing unauthorized modification to engine control software or an engine control system of for example, a refrigerated transport application is provided. Particularly, the embodiments described herein prevent unauthorized parties from inadvertently or intentionally making changes to the engine control software used for controlling the engine or the engine control system that could, for example, potentially bypass emission strategies implemented in the refrigerated transport application. Accordingly, emission strategies such as, for example, EPA Tier IV not-to-exceed (NTE) regulations can be maintained.