A hearing aid on-chip system based on accuracy optimized front- and back-end blocks is presented for enhancing the signal processing accuracy of the hearing aid. Compared with the conventional system, the accuracy optimized system is characterized by the dual feedback network and the gain compensation technique used in the front-andback-endblocks,respectively,soastoalleviatethenonlinearitydistortioncausedbytheoutputswing.By usingthetechnique,theaccuracyofthewholehearingaidsystemcanbesignificantlyimproved.Theprototypechip has been designed with a 0.13 m standard CMOS process and tested with 1 V supply voltage. The measurement results show that, for driving a 16 loudspeaker with a normalized output level of 300 mV p-p, the total harmonic distortion reached about60 dB, achieving at least three times reduction compared to the previously reported works. In addition, the typical input referred noise is only about 5 υV rms. A hearing aid on-chip system based on accuracy optimized front- and back-end blocks is presented for enhancing the signal processing accuracy of the hearing aid. Compared to the conventional system, the accuracy optimized system is characterized by the dual feedback network and the gain compensation technique technique used in the front-and-back-end blocks, respectively, so that the output is derived. By using the technique, the impulse thehewholehearing aidsystem canbesignificantlyimproved.Theprototypechip has been designed with a 0.13 m standard CMOS process and tested with a 1 Vsupply voltage. The measurement results show that for driving a 16 loudspeaker with a normalized output level of 300 mV pp, the total harmonic distortion reached about 60 dB, achieving at least three times reduction compared to the previously reported works. In addition, the typical input referred noise is only about 5 υV rms.