Title :
Low Frequency Noise Reduction Using Multiple Transistors With Variable Duty Cycle Switched Biasing
Author :
Jainwal, Kapil ; Shah, Kushal ; Sarkar, Mukul
Author_Institution :
Dept. of Electr. Eng., Indian Inst. of Technol. Delhi, New Delhi, India
Abstract :
Randomization of the trap state of defects present at the gate Si-SiO2 interface of MOSFET is responsible for the low-frequency noise phenomena such as random telegraph signal (RTS) and 1/f noise. Random activity of trapping and de-trapping of mobile charge carriers, in to these defects, can be reduced by switching the device ON and OFF periodically. The analysis of the low-frequency noise considers the non-stationary behavior of traps in time-periodic biasing conditions. In this paper, analysis of the low-frequency noise by deriving a model for RTS noise power spectral density for variable duty cycle switched biasing, is presented. It is concluded that the low-frequency noise can be reduced by using a multi-stage configuration of multiple transistors in place of a single transistor. In this configuration, each transistor has a decreased duty cycle and it is shown from simulation that the noise reduction obtained can be as large as 26 dB for a 40 stage configuration.
Keywords :
1/f noise; MOSFET; semiconductor device noise; silicon; silicon compounds; 1/f noise; MOSFET; RTS noise power spectral density; Si-SiO2; defects trap state; low frequency noise reduction; mobile charge carrier; multiple transistor; noise reduction; random telegraph signal; variable duty cycle switched biasing; 1f noise; CMOS image sensors; Low-frequency noise; Noise reduction; Stochastic processes; 1/ ${f}$ noise; 1/f noise; CMOS image sensors; Low-frequency noise; Noise model; Non-stationary noise; Random telegraph signal (RTS) noise; Stochastic process; low-frequency noise; noise model; non-stationary noise; random telegraph signal (RTS) noise; stochastic process;
Journal_Title :
Electron Devices Society, IEEE Journal of the
DOI :
10.1109/JEDS.2015.2473694
