A 0.1% THD, 1-M<inline-formula> <tex-math notation="LaTeX">$\Omega$ </tex-math> </inline-formula> to 1-G<inline-formula> <tex-math notation="LaTeX">$\Omega$ </tex-math> </inline-formula> Tunable, Temperature-Compensated Transimpedance Amplifier Using a Multi-Element Pseudo-Resistor

Abstract

In this paper, a transimpedance amplifier (TIA) is presented that utilizes a modified pseudo-resistor (PR) with improved robustness against temperature and process variations, enhanced linearity, and reduced parasitics. Using a biasing scheme named pseudo current mirror, the conventional dependence on absolute process parameters is reduced to a dependence on matching of alike devices. The linearity and noise performance as well as the immunity against process variations of the presented TIA are improved by the series connection of multiple PR elements. Moreover, it is shown how implementing the design in a silicon-on-insulator (SOI) technology reduces critical parasitics, which in turn enables the use of the multi-element PR in high-speed, high-gain, and low-distortion TIAs. A prototype realization in a 180-nm CMOS SOI technology achieves a tunability in transimpedance of three orders of magnitude from ${1}~{\mathrm {G}\Omega }$ down to ${1}~{\mathrm {M}\Omega }$ with corresponding bandwidths from ${8}~{\mathrm {kHz}}$ to 2 MHz. By design, the contribution of shot noise is rendered negligible and the white noise floor of the prototype realization approaches the theoretical thermal noise limit, e.g., ${5.5}~{\mathrm {fA}/\sqrt {\mathrm {Hz}}}$ for a transimpedance of ${1}~{\mathrm {G}\Omega }$ and ${140}~{\mathrm {fA}/\sqrt {\mathrm {Hz}}}$ for ${1}~{\mathrm {M}\Omega }$ . Total harmonic distortion values of less than 0.1% are achieved for an input amplitude of ${300}\,\,{\mathrm {pA}_{\mathrm {p{-}p}}}$ for ${1}~{\mathrm {G}\Omega }$ , ${4.0}\,\,{\mathrm {nA}_{\mathrm {p{-}p}}}$ for ${100}~{\mathrm {M}\Omega }$ , and ${40}\,\,{\mathrm {nA}_{\mathrm {p{-}p}}}$ for ${10}~{\mathrm {M}\Omega }$ , and less than 1% is achieved for an input amplitude of ${550}\,\,{\mathrm {nA}_{\mathrm {p{-}p}}}$ for ${1}~{\mathrm {M}\Omega }$ . The presented TIA consumes an area of 0.07 mm2 and dissipates a power of 9.3 mW for the opamp and a maximum power of 0.2 mW for the PR from a 1.8-V supply.