Switching controlling circuit, converter using the same, and switching controlling method

What is claimed is: 1 . A converter, comprising: a switching unit; an energy storage unit storing energy from DC input power and then generating an output voltage, depending on a switching operation of the switching unit; and a switching control unit turning on the switching unit when a voltage between one terminal and the other terminal of the switching unit reaches a lowest point of a resonance waveform, wherein the switching control unit includes: a voltage detection unit detecting the voltage between one terminal and the other terminal at the time of the resonance waveform; a first signal output unit outputting a first signal when the voltage detected by the voltage detection unit reaches a change point of a slope corresponding to the lowest point of the resonance waveform; and a switching driving unit turning on the switching unit in response to the first signal. 2 . The converter according to claim 1 , wherein a voltage level of the DC input power is more than 50% of a voltage level of the output voltage. 3 . The converter according to claim 1 , wherein the first signal output unit outputs the first signal when the slope of voltage detected by the voltage detection unit is changed from a negative direction to a positive direction. 4 . The converter according to claim 1 , wherein the first signal output unit includes a differentiator having one terminal connected to the voltage detection unit to detect information on the slope of voltage detected by the voltage detection unit. 5 . The converter according to claim 4 , wherein the first signal output unit outputs the first signal when a direction of current flowing in the differentiator is changed from a negative direction to a positive direction. 6 . The converter according to claim 4 , wherein the first signal output unit outputs the first signal together with detecting the change point of the slope, depending on an enable signal, and the first signal output unit further includes: a first comparator comparing a differential voltage corresponding to a current flowing in the differentiator with a first reference voltage and outputs a comparison signal depending on a comparison result; and a signal output terminal outputting the first signal depending on the comparison signal. 7 . The converter according to claim 6 , wherein the first comparator includes an inversion input terminal and a non-inversion input terminal, and the inversion input terminal is applied with the first reference voltage and the non-inversion input terminal is applied with the differential voltage. 8 . The converter according to claim 6 , wherein the first reference voltage is a voltage obtained by sampling and holding the differential voltage when no change in slope is present. 9 . The converter according to claim 6 , wherein the first signal output unit further includes: a voltage holding unit connected to the other terminal of the differentiator and constantly holding the differential voltage when the enable signal is turned on and off; and a voltage level reducing unit connected to the first comparator and lowering a voltage level of the first reference voltage. 10 . The converter according to claim 6 , wherein the first signal output unit further includes: a delay unit which delays the time until the first signal is output after the enable signal is turned on. 11 . The converter according to claim 4 , wherein the first signal output unit further includes: a clamping transistor between the voltage detection unit and one terminal of the differentiator. 12 . The converter according to claim 11 , wherein the first signal output unit further includes: a clamping voltage comparison unit which outputs the first signal when a voltage clamped by the clamping transistor is equal to or less than a zero voltage. 13 . The converter according to claim 1 , further comprising: a sensing resistor connected between the other terminal of the switching unit and a ground. 14 . The converter according to claim 13 , wherein the switching control unit further includes: a second signal output unit outputting a second signal using a feedback voltage corresponding to the output voltage and a sensing voltage which is generated from the sensing resistor. 15 . The converter according to claim 14 , wherein the switching driving unit turns off the switching unit in response to the second signal. 16 . The converter according to claim 14 , wherein the switching driving unit includes: a third signal output unit outputting a third signal depending on the first and second signals; and a switching driving signal output unit outputting a switching driving signal depending on the third signal to turn on/off the switching unit. 17 . The converter according to claim 14 , wherein the second signal output unit includes: a second comparator comparing the feedback voltage with a second reference voltage to output a comparison voltage depending on a comparison result; and a third comparator comparing the sensing voltage with the comparison voltage to output the second signal depending on a comparison result. 18 . The converter according to claim 17 , wherein the second signal output unit further includes: a comparison voltage dividing unit connected between an output terminal of the second comparator and an input terminal of the third comparator and dividing the comparison voltage output from the second comparator and outputting a divided voltage to the input terminal of the third comparator. 19 . The converter according to claim 1 , wherein the voltage detection unit is configured of a plurality of capacitors connected between one terminal of the switching unit and a ground. 20 . The converter according to claim 17 , wherein the second comparator includes an inversion input terminal and a non-inversion input terminal, and the inversion input terminal is applied with the feedback voltage and the non-inversion input terminal is applied with the second reference voltage. 21 . The converter according to claim 17 , wherein the third comparator includes an inversion input terminal and a non-inversion input terminal, and the inversion input terminal is applied with the comparison voltage and the non-inversion input terminal is applied with the sensing voltage. 22 . The converter according to claim 1 , wherein the switching unit is connected to a snubber capacitor in parallel. 23 . A switching control circuit controlling a switching operation of a switching device which controls a generation of an output voltage from DC input power by an energy storage device and turning on the switching device when a voltage between one terminal and the other terminal of the switching device reaches a lowest point of a resonance waveform, the switching control circuit comprising: a voltage detection unit detecting the voltage between one terminal and the other terminal at the time of the resonance waveform; a first signal output unit outputting a first signal when the voltage detected by the voltage detection unit reaches a change point of a slope corresponding to the lowest point of the resonance waveform; and a switching driving unit turning on the switching device in response to the first signal. 24 . The switching control circuit according to claim 23 , wherein a voltage level of the DC input power is more than 50% of a voltage level of the output voltage. 25