Method for transmitting and receiving signal in wireless communication system and apparatus for performing same

What is claimed is: 1. A method for receiving a signal by a first user equipment (UE) in a wireless communication system supporting non-orthogonal multiple access (NOMA), the method comprising: receiving a NOMA signal in which a signal for the first UE and a signal for a second UE are superposed, the first UE and the second UE belonging to a same NOMA pair; and demodulating the signal for the first UE from the NOMA signal based on at least part of a NOMA constellation configured based on downlink transmit power and modulation order for the second UE, wherein only a bit is differently configured between bit sequences of NOMA constellation points adjacent to each other in the NOMA constellation, wherein complex coordinates (I, Q) of the NOMA constellation points are determined based on a combination of downlink transmit power for the first UE and downlink transmit power for the second UE, and wherein upper or lower N bits (c 1 c 2 . . . c N ) in a bit sequence with a length of (M+N), which is mapped to each of the NOMA constellation points, are defined according to the following equation: c 1 =((( a 1 ⊗a 3 ) ⊗a 5 ) . . . ⊗a M−1 ) {circle around (z)}b 1 c 2 =((( a 2 ⊗a 4 ) ⊗a 6 ) . . . ⊗a M ) {circle around (z)}b 2 c i =b i (3≤ i≤N ),   [Equation] where ‘⊗’ and ‘{circle around (z)}’ are identical or different predetermined bit-wise operations, ‘b1b2 . . . bN’ is a bit sequence for the first UE, ‘a1a2 . . . aM’ is a bit sequence for the second UE, ‘M’ and ‘N’ are integers, ‘M’ is modulation order of the second UE, and ‘N’ is a number of bits corresponding to modulation order of the first UE. 2. The method of claim 1 , wherein the demodulating the signal for the first UE comprises either demodulating the signal for the first UE in a maximum likelihood (ML) manner by constructing an entirety of the NOMA constellation or demodulating the signal for the first UE in a successive interference cancellation (SIC) scheme by reconstructing constellation points corresponding to a part of the NOMA constellation. 3. The method of claim 1 , wherein remaining M bits in the (M+N)-length bit sequence are configured to be identical to the bit sequence of the second UE, ‘a1a2 . . . aM’, and wherein the predetermined bit-wise operations include at least one of an exclusive OR (XOR) operation and a not exclusive OR (XNOR) operation. 4. The method of claim 1 , further comprising: demodulating the signal for the second UE using a first constellation corresponding to the modulation order for the second UE; cancelling the signal for the second UE from the NOMA signal using a result obtained by demodulating the signal for the second UE; and demodulating and decoding the signal for the first UE using a residual signal after cancelling and a second constellation corresponding to modulation order for the first UE. 5. The method of claim 4 , further comprising: performing a not exclusive OR (XNOR) operation between results of the XNOR operation of odd-indexed bits of a bit sequence of the second UE and respective first bits of bit sequences of a reference constellation corresponding to the modulation order of the first UE; performing the XNOR operation between results of the XNOR operation of even-indexed bits of the bit sequence of the second UE and respective second bits of the bit sequences of the reference constellation; and generating a second constellation by inserting results of the XNOR operation for the respective first bits and results of the XNOR operation for the respective second bits into the reference constellation. 6. The method of claim 1 , wherein the NOMA constellation includes M2 constellation point groups, each having N2 constellation points, and wherein spacing between N2 constellation points belonging to a same constellation point group is determined based on the downlink transmit power for the first UE and spacing between centers of the M2 constellation point groups is determined based on the downlink transmit power of the second UE. 7. The method of claim 1 , further comprising: transmitting information on a receiver type of the first UE to a base station, wherein the receiver type includes at least one of a maximum likelihood (ML) type and a successive interference cancellation (SIC) type. 8. A first user equipment (UE) for receiving a signal in a wireless communication system supporting non-orthogonal multiple access (NOMA), the first UE comprising: a receiver configured to receive a NOMA signal in which a signal for the first UE and a signal for a second UE are superposed, the first UE and the second UE belonging to a same NOMA pair; and a processor configured to demodulate the signal for the first UE from the NOMA signal based on at least part of a NOMA constellation configured based on downlink transmit power and modulation order for the second UE, wherein only a bit is differently configured between bit sequences of NOMA constellation points adjacent to each other in the NOMA constellation, wherein complex coordinates (I, Q) of the NOMA constellation points are determined based on a combination of downlink transmit power for the first UE and downlink transmit power for the second UE, and wherein upper or lower N bits (c1c2 . . . cN) in a bit sequence with a length of (M+N), which is mapped to each of the NOMA constellation points, are defined according to the following equation: c 1 =((( a 1 ⊗a 3 ) ⊗a 5 ) . . . ⊗a M−1 ) {circle around (z)}b 1 c 2 =((( a 2 ⊗a 4 ) ⊗a 6 ) . . . ⊗a M ) {circle around (z)}b 2 c i =b i (3≤ i≤N ),   [Equation] where ‘⊗’ and ‘{circle around (z)}’ are identical or different predetermined bit-wise operations, ‘b1b2 . . . bN’ is a bit sequence for the first UE, ‘a1a2 . . . aM’ is a bit sequence for the second UE, ‘M’ and ‘N’ are integers, ‘M’ is modulation order of the second UE, and ‘N’ is a number of bits corresponding to modulation order of the first UE. 9. A method for transmitting a signal by a base station (BS) in a wireless communication system supporting non-orthogonal multiple access (NOMA), the method comprising: determining a NOMA constellation by considering downlink transmit power and modulation order for each of a first user equipment (UE) and a second UE which belong to a same NOMA pair; modulating a NOMA signal in which a signal for the first UE and a signal second UE are superposed based on the NOMA constellation; and transmitting the NOMA signal, wherein only a bit is differently configured between bit sequences of NOMA constellation points adjacent to each other in the NOMA constellation, wherein complex coordinates (I, Q) of the NOMA constellation points are determined based on a combination of downlink transmit power for the first UE and downlink transmit power for the second UE, and wherein upper or lower N bits (c1c2 . . . cN) in a bit sequence with a length of (M+N), which is mapped to each of the NOMA constellation points, are defined according to the following equation: c 1 =((( a 1 ⊗a 3 ) ⊗a 5 ) . . . ⊗a M−1 ) {circle around (z)}b 1 c 2 =((( a 2 ⊗a 4 ) ⊗a 6 ) . . . ⊗a M ) {circle around (z)}b 2 c i =b i (3≤ i≤N ),   [Equation] where ‘⊗’ and ‘{circle around (z)}’ are identical or different predetermined bit-wise operations, ‘b1b2 . . . bN’ is a bit sequence for the first UE, ‘a1a2 . . . aM’ is a bit sequence for the second UE, ‘M’ and ‘N’ are integers, ‘M’ is modulation order of the second UE, and ‘N’ is a number of bits corresponding to modulation order of the first UE. 10. The method of claim 9 , wherein remaining M bits in the (M+N)-length bit sequence ar