Abstract:
The delay locked loop (DLL) is widely used in the electronics industry for implementing
clock and data recovery circuits (CDR) in high-speed IOs. DLL contains first order
closed-loop architecture, aligns the output clock to the reference clock, and reduces
skew between two clocks across variations in process, voltage and temperature (PVT)
by the help of the delay line. This circuit is always stable as it is a single pole system.
DLLs can be broadly classified into two categories: analog DLL and digital DLL. The
analog DLL has an analog controlling input to control the delay offered by the delay
lines to reduce the skew between the input and the output clock of the DLL system.
Digital DLLs on the other hand, have quantized steps for delay change in the delay
line. This delay line is controlled by a digital code obtained from the controller. The
Digital DLLs can easily adopt to technology changes as they do not have strict voltage
headroom requirements like analog DLLs. Also, mostly standard cells are used to design
Digital DLL which makes them portable. These characteristics make Digital DLLs an
attractive choice for implementing clock and data recovery circuits for very advanced
technologies.Lock time is one of the important parameter while designing DLL. It is decided by
the type of controlling mechanism used in implementing DLL. In order to reduce the
lock time, in this thesis work, the controller is implemented by Successive Approximation
Register which reduces the lock time for proposed DLL by using binary search algorithm.
To track the PVT variations, the SAR used has been modi_ed in such a manner that
it uses binary search algorithm for locking the DLL and then turns into a counter, to
track the PVT variations after locking. This DLL is designed in TSMC16nm FinFET
technology. This technology has its own limitations with respect to the delay offered by
the inverters and the amount of current an inverter can support. In order to mitigate
the current consumption and hence power consumption, a timing controller has been
proposed which helps the delay line achieving a resolution as small as 5ps for a frequency
of 400 MHz whereas the state-of-art study shows that for lower frequencies, a delay resolution
of at least 10ps has been reported. This circuit has a power consumption of only
240_W across corners whereas the state-of-the work has reported a power consumption
in order of mW. The phase accuracy of the designed Digital DLL is 99.5% across corners
in locked condition.