In-vehicle electronic control unit

What is claimed is: 1. An in-vehicle electronic control unit (ECU) comprising: a signal process circuit that receives and processes a sensor output signal from a sensor; a multi-channel A/D converter that performs an A/D conversion of the sensor output signal that has been processed by the signal process circuit; a microcomputer that processes an A/D conversion value that is derived from the A/D conversion of the sensor output signal by the multi-channel A/D converter; a first voltage generator and a second voltage generator that switch an output voltage according to an instruction from the microcomputer; and an input signal switcher that switches the sensor output signal for input into the signal process circuit according to an instruction from the microcomputer, the sensor output signal for input is either (i) the sensor output signal from the sensor or (ii) a first output signal generated by the first voltage generator or a second output signal generated by the second voltage generator, wherein (A) the signal process circuit divides the sensor output signal that is input to the ECU into a first signal and a second signal, the first signal is input into a first input terminal of the multi-channel A/D converter and the second signal is input into a second input terminal of the multi-channel A/D converter after an amplification of the signal by an amplification circuit, (B) the microcomputer has a first voltage controller, a second voltage controller, and an identification unit, wherein the first voltage controller adjusts an output voltage of the first voltage generator until the second signal input into the second input terminal of the multi-channel A/D converter 1) reaches a voltage value that is within an inputtable voltage range of the second input terminal and 2) is close to a lower limit of the inputtable voltage range when the first output signal generated by the first voltage generator is input to the signal process circuit, the second voltage controller adjusts an output voltage of the second voltage generator until the second signal input to the second input terminal of the multi-channel A/D converter 1) reaches a voltage value that is within an inputtable voltage range of the second input terminal and 2) is close to an upper limit of the inputtable voltage range when the second output signal generated by the second voltage generator is input to the signal process circuit, and the identification unit models a linear function that linearly associates an input voltage of the amplification circuit with an output voltage of the amplification circuit and identifies the linear function of the input voltage of the amplification circuit based on (i) a first A/D conversion value and a second A/D conversion value at a time when the first output signal generated by the first voltage generator is input to the signal process circuit and (ii) a first A/D conversion value and a second A/D conversion value at a time when the second output signal generated by the second voltage generator is input to the signal process circuit. 2. The in-vehicle electronic control unit of claim 1 , wherein the sensor is an in-cylinder pressure sensor. 3. The in-vehicle electronic control unit of claim 1 , wherein the microcomputer receives an output signal of a crank angle sensor, and the microcomputer sends an instruction to the input signal switcher according to the output signal of the crank angle sensor. 4. The in-vehicle electronic control unit of claim 1 , wherein the first voltage controller adjusting the output voltage of the first voltage generator includes continuously adjusting the output voltage of the first voltage generator until the second signal input into the second input terminal of the multi-channel A/D converter 1) reaches the voltage value that is within the inputtable voltage range of the second input terminal and 2) is close to the lower limit of the inputtable voltage range when the first output signal generated by the first voltage generator is input to the signal process circuit, and the second voltage controller adjusting the output voltage of the second voltage generator includes continuously adjusting the output voltage of the second voltage generator until the second signal input into the second input terminal of the multi-channel A/D converter 1) reaches the voltage value that is within the inputtable voltage range of the second input terminal and 2) is close to the upper limit of the inputtable voltage range when the second output signal generated by the second voltage generator is input to the signal process circuit. 5. The in-vehicle electronic control unit of claim 1 , wherein the first voltage controller adjusting the output voltage of the first voltage generator includes repeatedly adjusting the output voltage of the first voltage generator until the second signal input into the second input terminal of the multi-channel A/D converter 1) reaches the voltage value that is within the inputtable voltage range of the second input terminal and 2) is close to the lower limit of the inputtable voltage range when the first output signal generated by the first voltage generator is input to the signal process circuit, and the second voltage controller adjusting the output voltage of the second voltage generator includes repeatedly adjusting the output voltage of the second voltage generator until the second signal input into the second input terminal of the multi-channel A/D converter 1) reaches the voltage value that is within the inputtable voltage range of the second input terminal and 2) is close to the upper limit of the inputtable voltage range when the second output signal generated by the second voltage generator is input to the signal process circuit. 6. The in-vehicle electronic control unit of claim 1 , wherein the first voltage controller adjusting the output voltage of the first voltage generator includes adjusting the output voltage of the first generator until an amplified output voltage of the first voltage generator input into the second input terminal of the multi-channel A/D converter 1) reaches the voltage value that is within the inputtable voltage range of the second input terminal and 2) is close to the lower limit of the inputtable voltage range when the first output signal generated by the first voltage generator is input to the signal process circuit, and the second controller adjusting the output voltage of the second voltage generator includes adjusting the output voltage of the second generator until an amplified output voltage of the first voltage generator input into the second input terminal of the multi-channel A/D converter 1) reaches the voltage value that is within the inputtable voltage range of the second input terminal and 2) is close to the upper limit of the inputtable voltage range when the second output signal generated by the second voltage generator is input to the signal process circuit.