A self-sufficient Giga-Hertz digitally controlled ring oscillator for clock distribution network is presented in this paper. It features a high supply insensitivity in order to mitigate the additional jitter due to supply noise. This is achieved by inducing a mutual compensation between the oscillation frequency parameters that are affected by the supply voltage variations. The proposed method can be easily implemented and takes advantage of the deep sub-micrometer effects peculiar to topical CMOS technologies. We demonstrate by simulations that this approach remains efficient over process variations despite the reliability issue of short channel MOS transistors
Abstract. We have designed and implemented a flexible programmable multi-channel digitally-controlle...
Voltage Controlled Oscillator plays significant role in communication system design. The design of V...
Phase-locked loops (PLLs) are widely used in communication and digital systems to generate high freq...
A self-sufficient Giga-Hertz digitally controlled ring oscillator for clock distribution network is ...
Graduation date: 2010Modern day digital systems employ frequency\ud synthesizers to provide a common...
The regular downscaling of MOS transistors dimensions allows integrating a largest number of functio...
© 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
Voltage noise is the main source of dynamic variability in integrated circuits and a major concern f...
A method to reduce the supply voltage sensitivity of digitally-controlled ring oscillators (DCROs) u...
As the clock rates of microprocessors keep increasing, high data rate input/output (IO) should be de...
A method to reduce the supply voltage sensitivity of digitally-controlled ring oscillators (DCROs) u...
A reference clock generator is one of the most important components in many electronic devices. Comm...
Ring oscillators provide a central role in timing circuits for today?s mobile devices and desktop co...
A companion analysis of clock jitter and phase noise of single-ended and differential ring oscillato...
International audienceSelf-timed rings are promising for designing highspeed serial links and system...
Abstract. We have designed and implemented a flexible programmable multi-channel digitally-controlle...
Voltage Controlled Oscillator plays significant role in communication system design. The design of V...
Phase-locked loops (PLLs) are widely used in communication and digital systems to generate high freq...
A self-sufficient Giga-Hertz digitally controlled ring oscillator for clock distribution network is ...
Graduation date: 2010Modern day digital systems employ frequency\ud synthesizers to provide a common...
The regular downscaling of MOS transistors dimensions allows integrating a largest number of functio...
© 2019 IEEE. Personal use of this material is permitted. Permission from IEEE must be obtained for a...
Voltage noise is the main source of dynamic variability in integrated circuits and a major concern f...
A method to reduce the supply voltage sensitivity of digitally-controlled ring oscillators (DCROs) u...
As the clock rates of microprocessors keep increasing, high data rate input/output (IO) should be de...
A method to reduce the supply voltage sensitivity of digitally-controlled ring oscillators (DCROs) u...
A reference clock generator is one of the most important components in many electronic devices. Comm...
Ring oscillators provide a central role in timing circuits for today?s mobile devices and desktop co...
A companion analysis of clock jitter and phase noise of single-ended and differential ring oscillato...
International audienceSelf-timed rings are promising for designing highspeed serial links and system...
Abstract. We have designed and implemented a flexible programmable multi-channel digitally-controlle...
Voltage Controlled Oscillator plays significant role in communication system design. The design of V...
Phase-locked loops (PLLs) are widely used in communication and digital systems to generate high freq...