In the fifth generation (5G) communication system, massive connectivity of users and devices, higher spectral efficiency (SE), higher energy efficiency (EE), better link reliability and lower latency are expected. Since the current LTE system that uses the Orthogonal Frequency Division Multiple Access (OFDMA) technique is less efficient to meet these requirements, one of the most popular solutions for 5G is non-orthogonal multiple access (NOMA) technique. However, most current code-domain NOMA solutions require user-specific codebook assignment, which require grant based transmission. Therefore, the motivation is to design a code-domain NOMA scheme that can facilitate grant free random multiple access. In this thesis, the “Index Modulation Multiple Access”(IMMA) scheme is proposed. IMMA is a codebook-based NOMA scheme that is inspired from the index modulation (IM) technique. To be specific, IMMA uses the active subcarriers and inactive subcarriers to make index indices, and the index indices can carry index bits in addition to the modulation signal bits. By adjusting different active subcarrier numbers and modulation types, the IMMA can reconfig and improve the spectral efficiency (SE) and energy efficiency (EE). The rotation code is proposed to resolve the inter-user interference (IUI) in contention based multiple access. Furthermore, different decoders such as the breath-first search sphere decoder (BFS-SD) and depth-first search sphere decoder (DFS-SD) are proposed to relieve the high computational complexity of the joint maximum likelihood (JML) decoder, the theoretical average bit error rate (ABER) upper bound is also derived. Our simulation results show that the BER of IMMA is improved with rotation code for better diversity. The SE and EE of IMMA are also better than OFDMA and sparse code multiple access (SCMA). In brief, we design a code-domain NOMA scheme that can facilitate grant free random multiple access, and has better SE, EE than OFDMA and SCMA.