Power conversion device

The invention claimed is: 1. A power conversion device, comprising: a switching circuit including M switching elements connected in parallel to each other, where M is an integer of 2 or more; and a processing circuitry to control the switching circuit by controlling each of switching operations of the M switching elements, wherein the processing circuitry is configured to: select, in each first set cycle corresponding to an integer multiple of a switching cycle of the switching circuit, where the integer is 1 or more, a first target switching element and a second target switching element from the M switching elements, the number of first target switching elements being 1 or more and less than M, the number of second target switching elements being 1 or more and less than M; perform control so that, at a time of a turn-on operation of the switching circuit, a turn-on start time of the first target switching element is earlier by a first set time period than a turn-on start time of another switching element that is not the first target switching element, the first set time period being set so as to be equal to or longer than a turn-on time period in a turn-on operation of the first target switching element; and perform control so that, at a time of a turn-off operation of the switching circuit, a turn-off start time of the second target switching element is later by a second set time period than a turn-off start time of another switching element that is not the second target switching element, the second set time period being set so as to be equal to or longer than a turn-off time period in a turn-off operation of the another switching element that is not the second target switching element, and wherein the processing circuitry is further configured to determine, based on a parasitic inductance of a current path of each of the M switching elements, the number of times that each of the M switching elements is selected as the first target switching element in a second set cycle corresponding to an integer multiple of the first set cycle, where the integer is 2 or more, and the number of times that each of the M switching elements is selected as the second target switching element in the second set cycle. 2. The power conversion device according to claim 1 , wherein, in a second set cycle corresponding to an integer multiple of the first set cycle, where the integer is 2 or more, each of the M switching elements is selected as the first target switching element an equal number of times, and each of the M switching elements is also selected as the second target switching element an equal number of times. 3. The power conversion device according to claim 2 , wherein the another switching element is the first target switching element, and the first switching element is turned on from the turn-on start time of the first target switching element until the turn-off start time of the first target switching element, wherein M is three or more, the plurality of switching elements comprises a first switching element, a second switching element and a third switching element, a first switching loss of the power conversion device is reduced to approximately one third of a second switching loss, wherein the second switching loss corresponds to switching all switching elements of the plurality of switching elements at a same time. 4. A power conversion device, comprising: a switching circuit including M switching elements connected in parallel to each other, where M is an integer of 2 or more; a temperature detector configured to detect each of temperatures of the M switching elements or each of temperatures around the M switching elements; and a processing circuitry to control the switching circuit by controlling each of switching operations of the M switching elements, wherein the processing circuitry is configured to: select, in each first set cycle corresponding to an integer multiple of a switching cycle of the switching circuit, where the integer is 1 or more, a first target switching element and a second target switching element from the M switching elements, the number of first target switching elements being 1 or more and less than M, the number of second target switching elements being 1 or more and less than M; perform control so that, at a time of a turn-on operation of the switching circuit, a turn-on start time of the first target switching element is earlier by a first set time period than a turn-on start time of another switching element that is not the first target switching element, the first set time period being set so as to be equal to or longer than a turn-on time period in a turn-on operation of the first target switching element; and perform control so that, at a time of a turn-off operation of the switching circuit, a turn-off start time of the second target switching element is later by a second set time period than a turn-off start time of another switching element that is not the second target switching element, the second set time period being set so as to be equal to or longer than a turn-off time period in a turn-off operation of the another switching element that is not the second target switching element, wherein the processing circuitry is further configured to determine, based on each of the temperatures detected by the temperature detector, the number of times that each of the M switching elements is selected as the first target switching element in a second set cycle corresponding to an integer multiple of the first set cycle, where the integer is 2 or more, and the number of times that each of the M switching elements is selected as the second target switching element in the second set cycle. 5. The power conversion device according to claim 1 , wherein the processing circuitry is configured to control each of the switching operations of the M switching elements by controlling each of gate signals of the M switching elements. 6. A power conversion device, comprising: a switching circuit including M switching elements connected in parallel to each other, where M is an integer of 2 or more; a voltage detector configured to detect a drain-source voltage common among the M switching elements; and a current detector configured to detect each of drain currents of the M switching elements; and a processing circuitry to control the switching circuit by controlling each of switching operations of the M switching elements, wherein the processing circuitry is configured to: select, in each first set cycle corresponding to an integer multiple of a switching cycle of the switching circuit, where the integer is 1 or more, a first target switching element and a second target switching element from the M switching elements, the number of first target switching elements being 1 or more and less than M, the number of second target switching elements being 1 or more and less than M; perform control so that, at a time of a turn-on operation of the switching circuit, a turn-on start time of the first target switching element is earlier by a first set time period than a turn-on start time of another switching element that is not the first target switching element, the first set time period being set so as to be equal to or longer than a turn-on time period in a turn-on operation of the first target switching element; and perform control so that, at a time of a turn-off operation of the switching circuit, a turn-off start time of the second target switching element is later by a second set time period than a turn-off start time of another switching element that is not the second target switching element, the second set time period being set so as to be equal to or longer than a turn-off time period in a turn-off operation of the another switching element that is not the second target swit