Current detection apparatus and control apparatus of rotary electric machine

What is claimed is: 1. A current detection apparatus for application to a system including a direct-current power supply, an inverter including plural pairs of series-connected upper-arm switches and lower-arm switches, and a three-phase rotary electric machine connected to the inverter, the upper- and lower-arm switches of each pair being connected to a corresponding one phase of the three-phase rotary electric machine, an upper set of the upper-arm switches being connected to the direct-current power supply via a first bus, a lower set of the lower-arm switches being connected to the direct-current power supply via a second bus, first to third phase switches selected in one of the upper set of the upper-arm switches and the lower set of the lower-arm switches being respectively defined as first to third detection switches, the first to third phase switches corresponding to respective first to third phases of the three-phase rotary electric machine, the current detection apparatus comprising: an arm current detection unit configured to detect each of first to third phase currents having respective amplitudes and flowing in the three-phase rotary electric machine based on a potential difference between input and output terminals of the corresponding one of the first to third detection switches while the corresponding one of the first to third detection switches is on, the first to third detection switches being lower-arm switches in the lower set of the lower-arm switches, the first to third detection switches being commonly connected to a common signal ground of the current detection apparatus; a bus current detection unit configured to detect each of at least bus-based first to third phase currents corresponding to the first to third phases of the three-phase rotary electric machine based on a current flowing through one of the first and second buses; and an amplitude correction unit configured to correct all of the first to third phase currents detected by the arm current detection unit based on the bus-based first to third phase currents detected by the bus current detection unit such that the amplitudes of all of the respective first to third phase currents detected by the arm current detection unit match with each other, wherein the amplitude correction unit is configured to multiply all of the first to third phase currents detected by the arm current detection unit by a correction gain for all corresponding first to third phase currents, thus correcting all the first to third phase currents detected by the arm current detection unit, to reduce variations between the amplitudes. 2. The current detection apparatus according to claim 1 , wherein: the bus current detection unit includes a portion for measuring the current flowing through one of the first and second buses; and the amplitude correction unit is configured to correct the first to third phase currents detected by the arm current detection unit based on a temperature of the portion of the bus current detection unit in addition to the bus-based first to third phase currents detected by the bus current detection unit. 3. The current detection apparatus according to claim 2 , further comprising: a temperature measuring unit configured to measure the temperature of the portion of the bus current detection unit, and a gain calculation unit comprising: a temperature correction unit configured to correct the correction gain for each of the first to third phase currents to thereby decrease the correction gain for each of the first to third phase currents as the measured temperature of the portion of the bus current detection unit increases. 4. The current detection apparatus according to claim 1 , wherein: the bus current detection unit is configured to sequentially detect peak values of the respective bus-based first to third phase currents; and the amplitude correction unit is configured to correct the first to third phase currents detected by the arm current detection unit based on: the peak values of the bus-based first to third phase currents detected by the bus current detection unit; and peak values of the first to third phase currents detected by the arm current detection unit. 5. The current detection apparatus according to claim 4 , further comprising: a gain calculation unit configured to divide the peak value of each of the bus-based first to third phase currents detected by the bus current detection unit by the peak value of the corresponding one of the first to third phase currents detected by the arm current detection unit, thus calculating the correction gain for each of the first to third phase currents detected by the arm current detection unit. 6. The current detection apparatus according to claim 5 , further comprising: a storage unit configured to store the correction gains for the respective first to third phase currents calculated by the gain calculation unit, wherein the amplitude correction unit is configured to correct the first to third phase currents based on the correction gains for the respective first to third phase currents stored in the storage unit during a start of the three-phase rotary electric machine. 7. The current detection apparatus according to claim 1 , wherein the first to third detection switches are lower-arm switches selected in the lower set of the lower-arm switches. 8. The current detection apparatus according to claim 1 , wherein the arm current detection unit is configured to detect the at least first to third phase currents based on the potential differences between the input and output terminals of the respective first to third detection switches while the first to third detection switches are simultaneously on. 9. The current detection apparatus according to claim 1 , wherein each of the arm current detection unit and bus current detection unit comprises: a pulse running circuit comprising: a plurality of inverting circuits connected in series, each of the inverting circuits being configured to perform an inverting operation of inverting a logical value of an input signal to output an inverted signal, and to have a time of the inversion operation changing on a power supply voltage, the inverting circuits including a start inverting circuit configured such that the inverting operation thereof is externally controllable, the inverting circuits being configured to run a pulse signal in response to activation of the start inverting circuit; a signal input terminal connected to a common power supply line of the inverting circuits and configured such that an analog voltage signal based on a corresponding one of the first phase current, the second phase current, the third phase current, the bus-based first phase current, the bus-based second phase current, the bus-based third phase current is input thereto as a power supply voltage of each of the inverting circuits; a running position detection unit configured to detect a running position of the pulse signal in the pulse running circuit based on an output signal of each of the inverting circuits, thus generating digital data corresponding to the detected running position of the pulse signal; and a signal processing unit configured to capture the digital data generated by the running position detection unit, and generate, based on the captured digital data, binary digital data, the running position detection unit being configured to detect the running position of the pulse signal in the pulse running circuit at a timing when a predetermined time passes after start of running of the pulse signal by the pulse running circuit. 10. A control apparatus for controlling a controlled variable of a three-phase rotary electric machine of a system includin