Electric power converter with a voltage controller and a current controller

The invention claimed is: 1. An electric power converter which converts a DC power to an AC power and produces a sinusoidal AC voltage and sinusoidal AC current from an output terminal, comprising: a reference voltage generator which generates a reference signal representing an AC voltage to which the DC power is to be converted; a voltage calculator which calculates, based on the reference signal, a target voltage; a voltage-side controller which controls a voltage between a first terminal and the output terminal to be equal to or nearly equal to the target voltage, whereby a voltage produced from the output terminal is a sinusoidal AC voltage; a current detector which detects a present current flowing through the output terminal; a current calculator which calculates, based on the target voltage and the present current, a target current to be flowing from a second terminal to the output terminal; and a current-side controller which controls the current flowing from the second terminal to the output terminal to be equal to or nearly equal to the target current, wherein said voltage calculator calculates the following equation: V tar= Vpc−k*V ref wherein Vtar is the target voltage between the first terminal and the output terminal, Vpc is a voltage between the first terminal and a center terminal, which is a center of the DC power, Vref is a voltage of the reference signal, and k is a predetermined constant. 2. An electric power converter according to claim 1 , wherein said current calculator calculates the following equation: I tar= Irn=I out( Vrp )/(2 Vpc )  (2) wherein Irn is the target current flowing from the output terminal to the second terminal, and Iout is a current detected by the current detector. 3. An electric power converter according to claim 1 , wherein said voltage-side controller comprises: a first plurality of switching modules connected between said first terminal and said output terminal and each switching module having a capacitor for charging a predetermined voltage, wherein said first plurality of switching modules produces a voltage obtained by a series connection of capacitors; a first plurality of voltage detectors provided to said first plurality of switching modules, respectively, wherein each of said first plurality of voltage detectors detects a voltage across the corresponding capacitor; an up-side controller which compares the voltage obtained by the series connection of capacitors with the target voltage, and controls switching modules to set the voltage obtained by the series connection of capacitors so that the voltage at the output terminal is equal to or nearly equal to the target voltage. 4. An electric power converter according to claim 1 , wherein said voltage-side controller comprises an operational amplifier. 5. An electric power converter according to claim 1 , wherein said current-side controller comprises an operational amplifier. 6. An electric power converter according to claim 3 , further comprising: a second plurality of switching modules connected between said second terminal and said output terminal and each switching module having a capacitor for charging a predetermined voltage, wherein said second plurality of switching modules produces a voltage obtained by a series connection of capacitors; a second plurality of voltage detectors provided to said second plurality of switching modules, respectively, wherein each of said second plurality of voltage detectors detects a voltage across the corresponding capacitor; an down-side controller which compares the voltage obtained by the series connection of capacitors with the target voltage, and controls switching modules to set the voltage obtained by the series connection of capacitors. 7. An electric power converter according to claim 6 , wherein said current-side controller comprises: a current controller which controls the current at the second terminal, said current controller having an inductor; a current detector which detects a present current flowing through the second terminal; and a switching controller which compares the present current with the target current, and controls the current controller to control the current at the second terminal to be equal to or nearly equal to the target current. 8. An electric power converter according to claim 7 , wherein said current controller comprises four transistors connected in a bridge circuit. 9. An electric power converter according to claim 7 , wherein said current controller is formed by said second plurality of switching modules and wherein said switch controller is formed by said down-side controller. 10. An electric power converter which converts an AC power to a DC power and produces a DC voltage and a DC current between a first terminal and a second terminal, comprising: a reference voltage generator which generates a reference signal representing an AC voltage which is synchronized with the AC voltage generated by the AC power source; a voltage calculator which calculates, based on the reference signal, a target voltage; a voltage-side controller which controls a voltage between a first terminal and the input terminal to be equal to or nearly equal to the target voltage, whereby a voltage produced between the first and second terminals is a DC voltage; a phase shifter which shifts a phase of the reference signal so that the AC voltage of the reference signal is phase shifted with the AC voltage generated by the AC power source; a current detector which detects a present current flowing through the input terminal; a current calculator which calculates, based on the target voltage and the present current, a target current to be flowing from a second terminal to the input terminal; and a current-side controller which controls the current flowing from the second terminal to the input terminal to be equal to or nearly equal to the target current, whereby the current flowing between the first and second terminals is a DC current, wherein said voltage calculator calculates the following equation: V tar= Vpc−k*V ref wherein Vtar is the target voltage between the first terminal and the output terminal, Vpc is a voltage between the first terminal and a center terminal, which is a center of the DC power, Vref is a voltage of the reference signal, and k is a predetermined constant.