Abstract: A master/slave configuration of a frequency locked Loop (FLL) decouples the process, target voltage, temperature (PVT) tracking goals of locking the loop from adapting the clock frequency in response to voltage droops in the supply. A master oscillator circuit receives a regulated supply voltage and supplies a master oscillator signal. A control circuit supplies a master frequency control signal to control a frequency of the master oscillator signal to a target frequency. A slave oscillator circuit is coupled to a regulated supply voltage and a droopy supply voltage and supplies a slave oscillator signal having a frequency responsive to a slave frequency control signal that is based on the master frequency control signal. The frequency of the second oscillator signal is further responsive to a voltage change of the droopy supply voltage.

Abstract: A master/slave configuration of a frequency locked Loop (FLL) decouples the process, target voltage, temperature (PVT) tracking goals of locking the loop from adapting the clock frequency in response to voltage droops in the supply. A master oscillator circuit receives a regulated supply voltage and supplies a master oscillator signal. A control circuit supplies a master frequency control signal to control a frequency of the master oscillator signal to a target frequency. A slave oscillator circuit is coupled to a regulated supply voltage and a droopy supply voltage and supplies a slave oscillator signal having a frequency responsive to a slave frequency control signal that is based on the master frequency control signal. The frequency of the second oscillator signal is further responsive to a voltage change of the droopy supply voltage.

Abstract: Systems, apparatuses, and methods for implementing dynamic clock control to increase stutter efficiency in a memory subsystem are disclosed. A system includes at least a processor, a memory, and a communication fabric coupled to the processor and memory. The system implements a stutter mode for a first region of the fabric, with stutter mode including an idle state and an active state. Stutter efficiency is defined as the idle time divided by the sum of the active time and the idle time. Reducing the exit latency of going from the idle state to the active state increases the stutter efficiency which increases the power savings achieved by implementing the stutter mode. Since the phase-locked loop (PLL) is one of the main contributors to the exit latency, the PLL is powered down and one or more bypass clocks are provided during the stutter mode.

Abstract: Systems, apparatuses, and methods for implementing dynamic clock control to increase stutter efficiency in a memory subsystem are disclosed. A system includes at least a processor, a memory, and a communication fabric coupled to the processor and memory. The system implements a stutter mode for a first region of the fabric, with stutter mode including an idle state and an active state. Stutter efficiency is defined as the idle time divided by the sum of the active time and the idle time. Reducing the exit latency of going from the idle state to the active state increases the stutter efficiency which increases the power savings achieved by implementing the stutter mode. Since the phase-locked loop (PLL) is one of the main contributors to the exit latency, the PLL is powered down and one or more bypass clocks are provided during the stutter mode.