Parallel combined output linear amplifier and operating method thereof

What is claimed is: 1. A parallel output linear amplifier, comprising: a transconductance amplifier configured to receive an analog input signal from an input terminal and amplify the analog input signal; a first pre-amplifier connected to the transconductance amplifier and configured to operate using a floating drive voltage; a cascode class AB amplifier connected to the first pre-amplifier and configured to provide an amplified signal to an output terminal; a second pre-amplifier connected to the transconductance amplifier and configured to operate using the floating drive voltage; and a cascade class AB amplifier connected to the second pre-amplifier and configured to provide an amplified signal to the output terminal. 2. The parallel output linear amplifier of claim 1 , wherein each of the first pre-amplifier and the second pre-amplifier comprises: a floating voltage source configured to trace an output voltage at the output terminal and provide the floating drive voltage; a first current amplifier connected to the transconductance amplifier and configured to operate using the floating voltage source; and a second current amplifier connected to the transconductance amplifier and configured to operate using the floating voltage source. 3. The parallel output linear amplifier of claim 1 , wherein the floating drive voltage is controlled according to a change of an output voltage at the output terminal. 4. The parallel output linear amplifier of claim 1 , wherein the cascode class AB amplifier comprises: a first cascode array including a first core device and a first input/output device that are connected in a cascode form; a first auxiliary amplifier that is connected between a source terminal and a gate terminal of the first input/output device in the first cascode array; a second cascode array including a second core device and a second input/output device that are connected in a cascode form, the second cascode array being symmetrically connected to the first cascode array; and a second auxiliary amplifier that is connected between a source terminal and a gate terminal of the second input/output device in the second cascode array. 5. The parallel output linear amplifier of claim 4 , wherein each of the first auxiliary amplifier and the second auxiliary amplifier maintains a drain-source voltage of a core device, which is connected to a respective input/output device, to be equal to a reference voltage. 6. The parallel output linear amplifier of claim 1 , wherein the cascode class AB amplifier comprises: a first cascode array including a first core device and a first input/output device that are connected in a cascode form; a first auxiliary amplifier connectable between a source terminal and a gate terminal of the first input/output device in the first cascode array; a first diode stack connectable to the source terminal of the first input/output device in the first cascode array; a first switch unit configured to connect one of the first auxiliary amplifier and the first diode stack to the first input/output device in the first cascode array; a second cascode array including a second core device and a second input/output device that are connected in a cascode form, the second cascode array being symmetrically connected to the first cascode array; a second auxiliary amplifier connectable between a source terminal and a gate terminal of the second input/output device in the second cascode array; a second diode stack connectable to the source terminal of the second input/output device in the second cascode array; and a second switch unit configured to connect one of the second auxiliary amplifier and the second diode stack to the second input/output device in the second cascode array. 7. The parallel output linear amplifier of claim 1 , wherein the cascade class AB amplifier: includes two input/output devices connected in a cascade form; or is set to have a transconductance and an output current that are higher than a transconductance and an output current of the cascode class AB amplifier at a crossing point of an output voltage of the output terminal; or is set to have a transconductance and an output current that are higher than a transconductance and an output current of the cascode class AB amplifier at a maximum value and a minimum value of an output voltage at the output terminal. 8. The parallel output linear amplifier of claim 1 , further comprising: a 3-stage amplifier configured to operate with a supply voltage that is lower than a minimum supply voltage value provided to the cascode class AB amplifier and the cascade AB class amplifier, wherein the third stage amplifier is connected between the input terminal and the output terminal. 9. An operating method of a parallel output linear amplifier, comprising: receiving, by a transconductance amplifier, an analog input signal from an input terminal; amplifying, by the transconductance amplifier, the analog input signal to generate a first amplified signal; generating, by a first pre-amplifier, a second amplified signal by amplifying the first amplified signal based on floating drive voltage; providing, by a cascode class AB amplifier, the second amplified signal to an output terminal; generating, by a second pre-amplifier, a third amplified signal by amplifying the first amplified signal based on the floating drive voltage; and providing, by a cascade class AB amplifier, the third amplified signal to the output terminal. 10. The operating method of claim 9 , wherein each of the first pre-amplifier and the second pre-amplifier comprises: a floating voltage source configured to trace an output voltage at the output terminal and provide the floating drive voltage; a first current amplifier connected to the transconductance amplifier and configured to operate using the floating voltage source; and a second current amplifier connected to the transconductance amplifier and configured to operate using the floating voltage source. 11. The operating method of claim 9 , wherein the floating drive voltage is controlled according to a change of an output voltage at the output terminal. 12. The operating method of claim 9 , wherein the cascode class AB amplifier comprises: a first cascode array including a first core device and a first input/output device that are connected in a cascode form; a first auxiliary amplifier that is connected between a source terminal and a gate terminal of the first input/output device in the first cascode array; a second cascode array including a second core device and a second input/output device that are connected in a cascode form, the second cascade array being symmetrically connected to the first cascode array; and a second auxiliary amplifier that is connected between a source terminal and a gate terminal of the second input/output device in the second cascode array. 13. The operating method of claim 12 , wherein each of the first auxiliary amplifier and the second auxiliary amplifiers maintains a drain-source voltage of a core device, which is connected to a respective input/output device, to be equal to a reference voltage. 14. The operating method of claim 9 , wherein the cascode class AB amplifier comprises: a first cascode array including a first core device and a first input/output device that are connected in a cascode form; a first auxiliary amplifier connectable between a source terminal and a gate terminal of the first input/output device in the first cascode array; a first diode stack connectable to the source terminal of the first input/output device in the first cascode array; a f