In-vehicle engine control apparatus

What is claimed is: 1. An in-vehicle engine control apparatus, comprising: a drive control circuit unit comprising a plurality of switching devices for sequentially driving electromagnetic coils of fuel injectors provided for respective cylinders of a multi-cylinder engine, in order to cause electromagnetic valves of said fuel injectors to open; a boost control circuit unit for generating a boosted high voltage for quickly magnetizing one of the plurality of electromagnetic coils; and a calculation control circuit unit comprising a microprocessor and a program memory as principal components, the program memory storing a control program controlling the generation of fuel injection command signals directed to the plurality of switching devices and for determining whether a given fuel injection command signal is to be generated once or a plurality of times during each fuel cycle period of one cylinder of the multi-cylinder engine, the boost control circuit unit comprising an inductive device to be intermittently magnetized by a boost switching device from an in-vehicle battery when the boost switching device is closed and a high voltage capacitor to be charged to a target voltage by a plurality of inductive device discharge operations in which electromagnetic energy accumulated in the inductive device is discharged when the boost switching device is opened, the boost switching device comprising a slew rate selection circuit for selecting a slew rate, which is a current increase rate through said boost switching device after a close command signal is fed to said boost switching device, from among a plurality of different boost switching device slew rate values, the program memory further comprising a control program and reference data, the control program serving to specify a selection value of the slew rate for the slew rate selection circuit, and the reference data comprising one of a data table and an approximation equation, the reference data comprising numerical data of a maximum permissible engine rotational speed determined by using the selection value specified for the slew rate selection circuit as a parameter, and using a measured environmental temperature relating to an operating environment of the boost switching device detected by an environmental temperature detector as a variable, the maximum permissible engine rotational speed being a largest speed such that an internal temperature of the boost switching device will be equal to or less than a predetermined permissible limit temperature even when, at the measured environmental temperature, the selection value of the slew rate is applied and a continuous operation is carried out while injection is carried out for a plurality of times, said maximum permissible engine rotational speed being based on statistical data of operating experiments, the control program being configured to compare a value of an engine rotational speed detected by an engine rotation sensor and a value of a maximum permissible engine rotational speed corresponding to a current measured environmental temperature to thereby determine the selection value, said maximum permissible engine rotational speed being calculated through interpolation from the reference data, the calculation control circuit unit being configured to select the selection value of the slew rate as small as possible under a condition that the internal temperature of the boost switching device, that will correspond to a current engine rotational speed and current measured environmental temperature, is equal to or less than the predetermined permissible limit temperature, to thereby suppress the current increase rate of the boost switching device. 2. An in-vehicle engine control apparatus according to claim 1 , wherein: the control program is further configured to perform a minimum selection value application function comprising specifying, when the engine rotational speed detected by the engine rotational sensor is less than a predetermined threshold rotational speed, the selection value at a lowest of said plurality of boost switching device slew rate values as the selection value of the slew rate for the slew rate selection circuit; and the threshold rotational speed is an engine rotational speed such that, when the engine rotational speed is less than the threshold rotational speed, the internal temperature of the boost switching device does not become more than a permissible limit value even when said lowest value of the slew rate is selected. 3. An in-vehicle engine control apparatus according to claim 1 , wherein: the control program is further configured to perform abnormality notification and high temperature environment determination functions; the high temperature environment determination function comprises generating an environment abnormality determination signal when the measured environmental temperature detected by the environmental temperature detector exceeds a predetermined reference environmental temperature; and the abnormality notification function comprises generating an abnormality notification output upon the occurrence of one of a state in which the environment abnormality determination signal is generated continues for at least a predetermined threshold period and a state in which the current engine rotational speed is higher than the permissible engine rotational speed acquired by referring to the current measured environmental temperature and the reference data continues for the predetermined threshold period or more after the selection value is set to a maximum level, to thereby carry out at least one of (a) storage of abnormality occurrence information or (b) stopping of multi-time injection control where the given fuel injection command signal is to be generated a plurality of times during each fuel cycle period of one cylinder of the multi-cylinder engine. 4. An in-vehicle engine control apparatus according to claim 3 , wherein: a value of said predetermined threshold period is equal to or more than a thermal time constant relating to an internal average temperature of the boost switching device; and the thermal time constant comprises a physical constant corresponding to an elapsed period from a change in power consumption of the boost switching device by a difference ΔP to occurrence of a temperature variation of 63% of a temperature difference value ΔTmax, where ΔTmax is a temperature difference such that the internal average temperature of the switching device saturates after one of a temperature increase by a temperature increase value +ΔTmax and a temperature decrease by a temperature decrease value −ΔTmax. 5. An in-vehicle engine control apparatus according to claim 3 , further comprising a neighborhood temperature detector arranged at a location closest to the boost switching device, wherein: the neighborhood temperature detector is configured to provide to said microprocessor an estimate of an internal average temperature of the boost switching device; the control program is further configured to perform a neighborhood temperature determination function comprising generating a high temperature abnormality determination signal when a value of the measured neighborhood temperature is more than a management target value acquired by subtracting a predetermined margin from the predetermined permissible limit temperature inside the boost switching device; and the abnormality notification function generates an abnormality notification output when the high temperature abnormality determination signal is generated, to thereby carry out at least one of the (i) storage of the abnormality occurrence information or (ii) the stopping of the multi-time injection control. 6. An in-vehicle engine control apparatus according to claim 2 , wherein: the co