As OFDM-based systems are widely adopted in today’s designs, many literatures of FFT processors, the arithmetic kernel of OFDM-based systems, can be found in the past decades. For a high performance FFT processor, many parameters should be decided carefully. In this thesis, we proposed a precision optimization flow to decide the scaling behavior at each stage with optimized output SQNR for FFT processor. The methodology utilizes the probability distribution to model the statistical behavior of the output at each stage. The noise from truncation and saturation arithmetic can be further analyzed to make the scaling decision. Without time-consuming and pattern-dependent simulations, the proposed method fixes the number format at each stage in a short time that gives optimized SQNR. The optimization flow has ability to handle different FFT sizes, FFT algorithms, wordlengths, and distributions of input signals. Experimental results designate that about 3 bits wordlength can be saved in 8K-point, radix-2 FFT processor, with no increasing in hardware complexity compared to traditional static scaling method. Furthermore, the precision is very close to the dynamic scaling method.