Voltage Controlled Ring Oscillator Design with Novel 3 Transistors XNOR/XOR Gates
Manoj Kumar, Sandeep Kumar Arya, Sujata Pandey
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DOI: 10.4236/cs.2011.23027   PDF    HTML     9,048 Downloads   16,640 Views   Citations

Abstract

In present work, improved designs for voltage controlled ring oscillators (VCO) using three transistors XNOR/XOR gates have been presented. Supply voltage has been varied from [1.8 - 1.2] V in proposed designs. In first method, the VCO design using three XNOR delay cells shows frequency variation of [1.900 - 0.964] GHz with [279.429 - 16.515] µW power consumption variation. VCO designed with five XNOR delay cells shows frequency variation of [1.152 - 0.575] GHz with varying power consumption of [465.715 - 27.526] µW. In the second method VCO having three XOR stages shows frequency variation [1.9176 - 1.029] GHz with power consumption variation from [296.393 - 19.051] µW. A five stage XOR based VCO design shows frequency variation [1.049 - 0.565] GHz with power consumption variation from [493.989 - 31.753] µW. Simulations have been performed by using SPICE based on TSMC 0.18µm CMOS technology. Power consumption and output frequency range of proposed VCOs have been compared with earlier reported circuits and proposed circuit’s shows improved performance.

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M. Kumar, S. Arya and S. Pandey, "Voltage Controlled Ring Oscillator Design with Novel 3 Transistors XNOR/XOR Gates," Circuits and Systems, Vol. 2 No. 3, 2011, pp. 190-195. doi: 10.4236/cs.2011.23027.

Conflicts of Interest

The authors declare no conflicts of interest.

References

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