A Hardware-Embedded Delay PUF (HELP) leverages entropy by monitoring path stability and measuring path delays from core logic macros. HELP incorporates techniques to deal with bias. A unique feature of HELP is that it may compare data measured from different test structures. HELP may be implemented in existing FPGA platforms. HELP may leverage both path stability and within-die variations as sources of entropy.

Methods and systems are described for receiving a reference clock signal and a phase of a local oscillator signal at a dynamically-weighted XOR gate comprising a plurality of logic branches, generating a plurality of weighted segments of a phase-error signal, the plurality of weighted segments including positive weighted segments and negative weighted segments, each weighted segment of the phase-error signal having a respective weight applied by a corresponding logic branch of the plurality of logic branches, generating an aggregate control signal based on an aggregation of the weighted segments of the phase-error signal, and outputting the aggregate control signal as a current-mode output for controlling a local oscillator generating the phase of the local oscillator signal, the local oscillator configured to induce a phase offset into the local oscillator signal in response to the aggregate control signal.

A Hardware-Embedded Delay PUF (HELP) leverages entropy by monitoring path stability and measuring path delays from core logic macros. HELP incorporates techniques to deal with bias. A unique feature of HELP is that it may compare data measured from different test structures. HELP may be implemented in existing FPGA platforms. HELP may leverage both path stability and within-die variations as sources of entropy.

A logic cell for a programmable logic integrated circuit having K function inputs, where K is the largest number such that the logic cell can compute any function of K inputs, and where the logic cell is configurable to implement one bit of a counter in parallel with any independent function of K-1 of the K inputs.

A compressor includes a logic circuit having transistors of a first channel type to receive a plurality of bit signals, and transistors of a second channel type, different from the first channel type, to receive the plurality of bit signals. The transistors of the first channel type are configured to generate an XOR logic output based on the plurality of bit signals, and the transistors of the second channel type are configured to generate, substantially simultaneous with the generation of the XOR logic output, an XNOR logic output based on the plurality of bit signals. The compressor includes NAND gates to receive multiplicand and multiplier bit signals.

Memory circuit for implementing logic operations and provided with memory cells, in particular of structure 6T, with a control circuit configured to activate the first access transistors or the second access transistors of at least two cells of the same given column and for detecting from a low- or high-voltage power supply line, from said given column, separate from the bit lines, a signal representative of the result of a logic operation having for operands data stored in said at least two cells.

In certain aspects, a clock generation circuit couples to a first clock having a first duty cycle and a second clock having the first duty cycle. The second clock lags the first clock by 90 degrees in phase. The clock generation circuit is configured to couple the output terminal to a ground when the first clock and the second clock both are at logic high and decouple the output terminal from the ground when at least one of the first clock and the second clock is at logic low and couple a supply voltage to the output terminal only when the first clock is at logic low and decouple the supply voltage from the output terminal when the first clock is at logic high. The clock generation circuit generates clock signals having a second duty cycle.

A pulse triggered flip flop circuit includes an exclusive OR clock generating stage that receives an input clock, data and produces an output clock pulse. The stage produces a output clock pulse that only goes away when the data is fully captured. The stage disables the output clock pulse only when the data is fully captured. Moreover, the circuit only toggles when the input data changes, reducing power consumption in some embodiments.

An example apparatus comprises an array of memory cells coupled to sensing circuitry including a first sense amplifier, a second sense amplifier, and a logical operation component. The sensing circuitry may be controlled to sense, via first sense amplifier, a data value stored in a first memory cell of the array, sense, via a second sense amplifier, a data value stored in a second memory cell of the array, and operate the logical operation component to output a logical operation result based on the data value stored in the first sense amplifier and the data value stored in the second sense amplifier.

Techniques and mechanisms for providing data to be used in an in-memory computation at a memory device. In an embodiment a memory device comprises a first memory array and circuitry, coupled to the first memory array, to perform a data computation based on data stored at the first memory array. Prior to the computation, the first memory array receives the data from a second memory array of the memory device. The second memory array extends horizontally in parallel with, but is offset vertically from, the first memory array. In another embodiment, a single integrated circuit die includes both the first memory array and the second memory array.