Dynamometer system control device

The invention claimed is: 1. A dynamometer system comprising: a dynamometer main body; a load which is connected to an output shaft of the dynamometer main body; an inverter which supplies electric power to the dynamometer main body according to a torque current command signal; a torque sensor which detects torque generated in a rocking piece of the dynamometer main body through a torque arm extended from the rocking piece; an angular velocity sensor which detects an angular velocity of the output shaft; and a control device which generates the torque current command signal based on detection signals of the torque sensor and the angular velocity sensor; wherein the control device includes: a loss computation unit which generates, based on a detection signal of the angular velocity sensor, a loss compensation signal corresponding to loss torque generated in the dynamometer main body in a state where the load is connected thereto; a natural vibration suppression control circuit which generates, with the torque current command signal, the detection signal of the torque sensor and the loss compensation signal, a correction signal for a high level torque command signal so as to suppress a natural vibration of the rocking piece; and a torque current command signal generation unit which inputs, to the inverter, the torque current command signal generated by subtracting the correction signal from the high level torque command signal, wherein the natural vibration suppression control circuit includes: a normative model computation unit which has an input/output characteristic simulating a characteristic from the torque current command signal to the detection signal of the torque sensor in the dynamometer system; a deviation compensator which generates a feedback signal with a deviation between an output torque signal from the normative model computation unit and the detection signal of the torque sensor so as to decrease the deviation; a model input generation unit which generates an input torque signal to the normative model computation unit with the feedback signal and a torque signal obtained by subtracting the loss compensation signal from the torque current command signal; and a differential compensator which generates the correction signal by performing a differential computation on the torque signal obtained in the normative model computation unit. 2. The dynamometer system according to claim 1 , wherein the loss computation unit includes a storage medium which stores a lookup table in which a correlation between a value of the detection signal of the angular velocity sensor and a value of the loss compensation signal corresponding to the value is prescribed, and generates the loss compensation signal for a value obtained by searching the lookup table with the value of the detection signal of the angular velocity sensor. 3. The dynamometer system according to claim 2 , wherein the load includes one or a plurality of auxiliary units connected to the output shaft, in the storage medium, a plurality of the lookup tables are stored which are different from each other so as to respectively correspond to combinations of the dynamometer main body and the auxiliary units connected to the dynamometer main body and the loss computation unit selects one of the lookup tables according to an operation of an operator, and generates the loss compensation signal for a value obtained by searching the selected lookup table with the value of the detection signal of the angular velocity sensor. 4. The dynamometer system according to claim 1 , wherein the loss computation unit includes a storage medium that stores a computation formula in which a value of the detection signal of the angular velocity sensor is an input and in which a value of the loss compensation signal corresponding to the input is an output, and generates the loss compensation signal for a value obtained by inputting the value of the detection signal of the angular velocity sensor to the computation formula. 5. The dynamometer system according to claim 4 , wherein the load includes one or a plurality of auxiliary units connected to the output shaft, in the storage medium, a plurality of the computation formulas are stored which are different from each other so as to respectively correspond to combinations of the dynamometer main body and the auxiliary units connected to the dynamometer main body and the loss computation unit selects one of the computation formulas according to an operation of an operator, and generates the loss compensation signal for a value obtained by inputting the value of the detection signal of the angular velocity sensor to the selected computation formula.