Abstract: Methods of enabling voice processing with minimal power consumption includes recording time-domain audio signal at a first clock frequency and a first voltage, and performing Fast Fourier Transform (FFT) operations on the time-domain audio signal at a second clock frequency to generate frequency-domain audio signal. The frequency domain audio signal may be enhanced to obtain better signal to noise ratio, through one or multiple filtering and enhancing techniques. The enhanced audio signal may be used to generate the total signal energy and estimate the background noise energy. Decision logic may determine from the signal energy and the background noise, the presence or absence of the human voice. The first clock frequency may be different from the second clock frequency.

Abstract: Described is an apparatus which comprises: a first power supply node to provide a first power supply; a second power supply node to provide a second power supply; a driver to operate on the first power supply, the driver to generate an output; and a receiver to operate on the second power supply, the receiver to receive the output from the driver and to generate a level-shifted output such that the receiver is operable to steer current from the second power supply to the first power supply.

Abstract: Embodiments include apparatuses, methods, and systems for voltage level shifting a data signal between a low voltage domain and a high voltage domain. In embodiments, a voltage level shifter circuit may include adaptive keeper circuitry, enhanced interruptible supply circuitry, and/or capacitive boosting circuitry to reduce a minimum voltage of the low voltage domain that is supported by the voltage level shifter circuit. Other embodiments may be described and claimed.

Abstract: Described is an apparatus including memory cell with retention using resistive memory. The apparatus comprises: memory element including a first inverting device cross-coupled to a second inverting device; a restore circuit having at least one resistive memory element, the restore circuit coupled to an output of the first inverting device; a third inverting device coupled to the output of the first inverting device; a fourth inverting device coupled to an output of the third inverting device; and a save circuit having at least one resistive memory element, the save circuit coupled to an output of the third inverting device.

Abstract: Embodiments include apparatuses, methods, and systems for voltage level shifting a data signal between a low voltage domain and a high voltage domain. In embodiments, a voltage level shifter circuit may include adaptive keeper circuitry, enhanced interruptible supply circuitry, and/or capacitive boosting circuitry to reduce a minimum voltage of the low voltage domain that is supported by the voltage level shifter circuit. Other embodiments may be described and claimed.

Abstract: Described is an apparatus including memory cell with retention using resistive memory. The apparatus comprises: a memory element including cross-coupled cells having a first node and a second node; a first transistor coupled to the first node; a second transistor coupled to the second node; and a resistive memory element coupled to the first and second transistors.

Abstract: Described is an apparatus which comprises: a first power supply node to provide a first power supply; a second power supply node to provide a second power supply; a driver to operate on the first power supply, the driver to generate an output; and a receiver to operate on the second power supply, the receiver to receive the output from the driver and to generate a level-shifted output such that the receiver is operable to steer current from the second power supply to the first power supply.

Abstract: Embodiments include apparatuses, methods, and systems for generation of an encryption key. In various embodiments, an authentication circuit may include a first bank of spin-torque nano-oscillators (STNOs) including a plurality of STNOs to generate respective oscillation signals and a second bank of STNOs including a plurality of STNOs to generate respective oscillation signals. The authentication circuit may further include a key generation circuit to select a first oscillation signal from the plurality of oscillation signals associated with the first bank of STNOs and a second oscillation signal from the plurality of oscillation signals associated with the second bank of STNOs. The key generation circuit may generate an encryption key based on a frequency of the first oscillation signal and a frequency of the second oscillation signal.

Abstract: Embodiments include apparatuses, methods, and systems for voltage level shifting a data signal between a low voltage domain and a high voltage domain. In embodiments, a voltage level shifter circuit may include adaptive keeper circuitry, enhanced interruptible supply circuitry, and/or capacitive boosting circuitry to reduce a minimum voltage of the low voltage domain that is supported by the voltage level shifter circuit. Other embodiments may be described and claimed.

Abstract: Embodiments include apparatuses, methods, and systems for generation of an encryption key. In various embodiments, an authentication circuit may include a first bank of spin-torque nano-oscillators (STNOs) including a plurality of STNOs to generate respective oscillation signals and a second bank of STNOs including a plurality of STNOs to generate respective oscillation signals. The authentication circuit may further include a key generation circuit to select a first oscillation signal from the plurality of oscillation signals associated with the first bank of STNOs and a second oscillation signal from the plurality of oscillation signals associated with the second bank of STNOs. The key generation circuit may generate an encryption key based on a frequency of the first oscillation signal and a frequency of the second oscillation signal.

Abstract: An aging monitor circuit that provides a more accurate estimate of aging and/or delay in a circuit and/or circuit path. The aging monitor circuit employs a separate aging path with driving and receiving flip flops (FFs) and a tunable replica circuit (TRC) to enable measurements of single-transition DC-stressed path delay that only propagates through stressed transistors or other circuit element(s). A finite state machine (FSM) in the aging monitor circuit is configured to adjust a frequency of a clock signal output by a digitally controlled oscillator (DCO) in response to an error signal output by the receiving FF. The error signal is generated in response to single-transition DC-stressed path delay; and therefore enables the adjustment of the frequency of the dock signal to correspond to an amount or effect of the delay.

Abstract: Methods of enabling voice processing with minimal power consumption includes recording time-domain audio signal at a first clock frequency and a first voltage, and performing Fast Fourier Transform (FFT) operations on the time-domain audio signal at a second clock frequency to generate frequency-domain audio signal. The frequency domain audio signal may be enhanced to obtain better signal to noise ratio, through one or multiple filtering and enhancing techniques. The enhanced audio signal may be used to generate the total signal energy and estimate the background noise energy. Decision logic may determine from the signal energy and the background noise, the presence or absence of the human voice. The first clock frequency may be different from the second clock frequency.

Abstract: An aging monitor circuit that provides a more accurate estimate of aging and/or delay in a circuit and/or circuit path. The aging monitor circuit employs a separate aging path with driving and receiving flip flops (FFs) and a tunable replica circuit (TRC) to enable measurements of single-transition DC-stressed path delay that only propagates through stressed transistors or other circuit element(s). A finite state machine (FSM) in the aging monitor circuit is configured to adjust a frequency of a clock signal output by a digitally controlled oscillator (DCO) in response to an error signal output by the receiving FF. The error signal is generated in response to single transition DC-stressed path delay, and therefore enables the adjustment of the frequency of the clock signal to correspond to an amount or effect of the delay.