Abstract: An apparatus and method are described, which prior to an event that could result in frequency overshoot, sends a signal to a voltage regulator or generator requesting a temporary supply voltage and/or current boost. This enables a clocking source, such as a phase locked loop (PLL) to lock fast while not needing any long-term voltage guard bands. The apparatus and scheme allows for on-the-fly change in supply voltage and/or clock frequency for a processor with little to no impact on Vmin. During the clock frequency overshoot, the supply voltage is temporarily boosted and then reduced down to the expected voltage level of the power supply. Such boost allows for absorbing the clock frequency overshoot impact. The supply voltage level can be reduced in a step-wise fashion to avoid any potential undershoot in clock frequency.

Abstract: A multi-feedback circuit that compares a duty cycle corrected reference clock fREF, and controls a number of identical delay lines to generate a new clock with a frequency that is a multiple (e.g., 32×, 4×, etc.) of the frequency of fREF with approximately 50% duty cycle (DC). The new clock is used as a reference clock to a phase locked loop (PLL) or a multiplying delay locked loop (MDLL) resulting in shorter lock times for the PLL/MDLL, higher bandwidth for the PLL/MDLL, lower long-term output clock jitter. The multi-feedback circuit can also be used as a low power clock generator.

Abstract: An apparatus and method are described, which prior to an event that could result in frequency overshoot, sends a signal to a voltage regulator or generator requesting a temporary supply voltage and/or current boost. This enables a clocking source, such as a phase locked loop (PLL) to lock fast while not needing any long-term voltage guard bands. The apparatus and scheme allows for on-the-fly change in supply voltage and/or clock frequency for a processor with little to no impact on Vmin. During the clock frequency overshoot, the supply voltage is temporarily boosted and then reduced down to the expected voltage level of the power supply. Such boost allows for absorbing the clock frequency overshoot impact. The supply voltage level can be reduced in a step-wise fashion to avoid any potential undershoot in clock frequency.

Abstract: A single droop detector and an asynchronous frequency recovery circuit may be used to slow down a frequency asynchronously when a voltage droop is detected and exit the droop event synchronously by gradually changing an electronic oscillator buffer capacitance until the frequency has been fully restored. This combination of a single droop detector and an asynchronous frequency recovery circuit may provide reduced detection and response latency. This solution may also provide improved performance in the presence of multiple voltage droop events that occur before a frequency has been fully restored from the previous droop. This solution also reduces or eliminates frequency overshoots and secondary voltage droops.

Abstract: An electronic device and associated methods are disclosed. In one example, the electronic device includes a MEMS die located within a substrate, and below a processor die. In selected examples, the MEMS die includes a resonator. Example methods of forming MEMS resonator devices are also shown.

Abstract: A wireless communication device for communicating across a wireless communication channel includes one or more processors configured to determine whether a further device is generating a radio frequency interference at an operating frequency; transmit a request message to the further device requesting the further device vacate the operating frequency based on the determination that the further device is generating radio frequency interference; receive a response message from the further device; and generate an instruction based on the response message.

Abstract: An apparatus and method is described that digitally coordinates dynamically adaptable clock and voltage supply to significantly reduce the energy consumed by a processor without impacting its performance or latency. A signal is generated that indicates a long latency operation. This signal is used to reduce power supply voltage and frequency of the adaptable clock. An early resume indicator is generated a few nanoseconds before normal operations are about to resume. This early resume signal is used to power up the power-downed voltage regulator, and/or can increase frequency and/or supply voltage back to normal level before normal processor operations are about to resume.

Abstract: An apparatus is provided for autonomous security and functional safety (FUSA) of clock and voltages. The apparatus may include: a multiplexer having a first input communicatively coupled to a pin to receive a first clock external to a die, and a second input coupled to an output of a divider; an oscillator to provide a second clock; and a counter coupled to an output of the multiplexer and the oscillator, wherein the counter is to operate with the second clock and is to determine a frequency of the first clock. The apparatus may further include a voltage monitor circuitry for monitoring voltage(s) for FUSA, a reference generator for FUSA, a duty cycle monitor for FUSA, a frequency degradation monitor for FUSA, and a phase error degradation monitor for FUSA.

Abstract: An apparatus and method to protect unauthorized change to a reference clock for a processor. The apparatus comprises: a first oscillator to generate a first clock; a second oscillator to generate a second clock; a third oscillator to generate a third clock; a first counter to count frequency of the first clock with respect to a fourth clock; a second counter to count frequency of the second clock with respect to the fourth clock; a third counter to count frequency of the third clock with respect to the fourth clock; and a circuitry to compare frequencies of the first, second, and third clocks with one another. The oscillators can be embedded in an interposer or package. These oscillators include one or more of: LC oscillator, micro electro-mechanical system (MEMs) based resonator, or ring oscillator.

Abstract: Some embodiments include apparatuses having a first path in a phase locked loop, the first path including a phase frequency detector to receive a first signal having a first frequency and a first node to provide a voltage; an oscillator coupled to a second node and the first node to provide a second signal having a second frequency at the second node; a second path including a frequency divider coupled to the second node and the phase frequency detector; and a circuit to generate digital information having a value based on a value of the voltage at the second node.

Abstract: A clock buffer or driver is gated pending reception of verifiable crypto keys. These clock buffer or divers remain gated, thus disabling a processor from any meaningful function, till crypto keys are decoded, verified, and applied to the clock buffer or driver. A low frequency pseudorandom frequency hopping time sequence is generated and used for randomizing spread-spectrum to modulate a reference clock (or output clock) of a frequency synthesizer. This hopping time sequence holds the key to unlocking the crypto keys. The PWM modulated crypto keys are carried by the hopping time sequence. To decode the PWM modulated crypto keys, the hopping time sequence is used. The reference clock which is modulated with crypto keys in the spread-spectrum is sent to a decoder (in a processor) along with the hopping time sequence. The crypto keys are decoded and then used to un-gate the clock buffer.

Abstract: A wireless communication device for communicating across a wireless communication channel includes one or more processors configured to determine whether a further device is generating a radio frequency interference at an operating frequency; transmit a request message to the further device requesting the further device vacate the operating frequency based on the determination that the further device is generating radio frequency interference; receive a response message from the further device; and generate an instruction based on the response message.

Abstract: Some embodiments include apparatuses having a first path in a phase locked loop, the first path including a phase frequency detector to receive a first signal having a first frequency and a first node to provide a voltage; an oscillator coupled to a second node and the first node to provide a second signal having a second frequency at the second node; a second path including a frequency divider coupled to the second node and the phase frequency detector; and a circuit to generate digital information having a value based on a value of the voltage at the second node.

Abstract: Examples relate to control apparatus, a control device, a method and a computer program for determining a device-specific supply voltage for a semiconductor device, and to a corresponding semiconductor device and corresponding systems. The control apparatus is configured to obtain measurement data of measurement circuitry of the semiconductor device, the measurement data being related to a progress of aging of the semiconductor device. The control apparatus is configured to determine the device-specific supply voltage of the semiconductor device based on the measurement data. The control apparatus is configured to provide information on the device-specific supply voltage for a supply voltage control apparatus.

Abstract: Some embodiments include apparatuses having a first path in a phase locked loop, the first path including a phase frequency detector to receive a first signal having a first frequency and a first node to provide a voltage; an oscillator coupled to a second node and the first node to provide a second signal having a second frequency at the second node; a second path including a frequency divider coupled to the second node and the phase frequency detector; and a circuit to generate digital information having a value based on a value of the voltage at the second node.

Abstract: An apparatus is provided which comprises: a frequency locked loop (FLL) comprising an oscillator including a plurality of delay stages, wherein an output of each delay stage is counted to determine a frequency of the FLL; and one or more circuitries coupled to the FLL to adjust a power supply to the FLL according to the determined frequency of the FLL.

Abstract: An apparatus is provided for low latency adaptive clocking, the apparatus comprises: a first power supply rail to provide a first power; a second power supply rail to provide a second power; a third power supply rail to provide a third power; a voltage divider coupled to the first, second, and third power supply rails; a bias generator coupled to voltage divider and the third power supply rail; an oscillator coupled to the bias generator and the first supply rail; and a clock distribution network to provide an output of the oscillator to one or more logics, wherein the clock distribution network is coupled to the second power supply rail.

Abstract: An apparatus is provided for mitigating uncertainties in process, voltage, random, and systematic variations between first and second dies. The first die comprises a clock compensator to adjust one or more signal characteristics of an input clock, and to provide first and second clocks; a data transmitter to sample data with a version of the first clock and to transmit the sampled data to a data receiver of the second die, wherein the data receiver is to receive the sampled data and generate a received data; and a clock transmitter to transmit the second clock to a clock receiver of the second die, wherein the clock receiver is to generate a third clock, wherein a phase of the third clock is adjusted to generate a fourth clock, wherein a delayed version of the fourth clock is received by a sampler coupled to the data receiver to sample the received data.

Abstract: A multi-feedback circuit that compares a duty cycle corrected reference clock fREF, and controls a number of identical delay lines to generate a new clock with a frequency that is a multiple (e.g., 32×, 4×, etc.) of the frequency of fREF with approximately 50% duty cycle (DC). The new clock is used as a reference clock to a phase locked loop (PLL) or a multiplying delay locked loop (MDLL) resulting in shorter lock times for the PLL/MDLL, higher bandwidth for the PLL/MDLL, lower long-term output clock jitter. The multi-feedback circuit can also be used as a low power clock generator.

Abstract: Some embodiments include apparatuses and methods of operating such apparatuses. One of the embodiments includes an input node to receive an input voltage, a circuit portion to generate first, second, and third voltages based on the input voltage, a comparator circuit to compare the first voltage with the second voltage to generate a first signal and to compare the first voltage with the third voltage to generate a second signal, and an output circuit to generate an output signal based on the first and second signals.