In order to verify the effectiveness of algorithms developed for hearing aids, developing a system that simulates the cochlear of the hearing impaired is in great demand. Thus, we investigate the model developed by Moore’s group in addressing threshold elevation, loudness recruitment, and reduced frequency selectivity of hearing impaired. The simulation about loudness was done by extracting the sub-band signal and powering the instantaneous magnitude according to the degree of recruitment. To simulate the frequency smearing, matrix multiplications of filter-bank coefficients of the normal/impaired cochlear were carried out. However, there are some drawbacks in Moore’s model. First, the minimum thresholds can not be set alone. Second, preserving the phase spectrum would mitigate the desired degree of magnitude smearing. Also, the spacing of the critical bands is restricted by FFT. Third, the computational cost is very high. To overcome these drawbacks, we (1) use a piecewise formula to decide the loudness sample by sample; (2) model the widened filter by a linear combination of normal filters and compute contributions from normal filters to each widened filter. Besides, we use white Gaussian noise to generate the band-passed carrier and synthesize the signal. Our approaches can be done in the same filter-bank architecture to reduce computational load. Last, listening tests are carried out to verify our model. Results show that our model not only acts like Moore’s model, but also exhibits characteristics reported by the hearing impaired.