Abstract
This paper presents a fast configurable automatic gain control (AGC) with strong focus on fast acting control and low power consumption. This AGC includes two paths, main amplification path and gain adjusting path. Using the gain adjusting path through an extra amplifier provides a way for tracking and comparing the input signal with four adjusted thresholds to be judged for selecting the appropriate gain value for main amplification path. This mechanism of gain control is done by reorganization of input level and changing the resistance of feedback in main amplification path to generate smooth variation gain, without any interruption or delay in signal flow through the variable gain amplifier. Moreover, in order to protect the user from intense transients in variations of the input signal level, output level of variable gain amplifier is directly monitored using optimum threshold to reduce the overall gain using feedback control mechanism. The minimum power is consumed by gain adjusting path has almost no considerable on power consumption, it greatly improves hearing quality. Meanwhile, using a large size PMOS differential pair at the input improved the noise performance. Proposed AGC designed and simulated in TSMC 130-nm CMOS process. The post layout simulation results the maximal SNR is 84.6 dB in 100 Hz–19.6 kHz band-width and the total consumption power of this AGC is 78 μW at 1 V supply voltage. In addition, its gain is varied smoothly between 20 to 57 dB. Achieved results demonstrate that designed AGC meet the requirement of analog front end of hearing aids.
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Koozehkanani, R.D., Makouei, S. & Toofan, S. A fast configurable AGC for front-end of digital hearing aids. Analog Integr Circ Sig Process 109, 367–377 (2021). https://doi.org/10.1007/s10470-021-01921-z
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DOI: https://doi.org/10.1007/s10470-021-01921-z