Provided is a FPGA-based design method for equally dividing an interval, including the following steps: dividing the oscillation periods of a second pulse signal of a crystal oscillator clock of a FPGA board by the number of equally divided sampling pulses, and obtaining the remainder thereof; dividing the remainder by the number of the equally divided sampling pulses to serve as an error within each sampling interval; using a counter to count from the second pulse, and stopping the counting of the counter once whenever the error within the sampling interval, which is accumulated within the second pulse interval, is greater than or equal to the vibration period. Further provided is a FPGA-based design device for equally dividing an interval. The present application makes full use of the feature of interval equal division calculation, has high precision, and is easy to implement.

Provided is a FPGA-based design method for equally dividing an interval, including the following steps: dividing the oscillation periods of a second pulse signal of a crystal oscillator clock of a FPGA board by the number of equally divided sampling pulses, and obtaining the remainder thereof; dividing the remainder by the number of the equally divided sampling pulses to serve as an error within each sampling interval; using a counter to count from the second pulse, and stopping the counting of the counter once whenever the error within the sampling interval, which is accumulated within the second pulse interval, is greater than or equal to the vibration period. Further provided is a FPGA-based design device for equally dividing an interval. The present application makes full use of the feature of interval equal division calculation, has high precision, and is easy to implement.

A fractional-N phase locked loop (PLL) and a sliced charge pump (CP) control method thereof are provided. The fractional-N PLL includes a first current source, a first phase frequency detector (PFD), a second current source, a second PFD, and a divided clock controller. The first current source provides a first current. The first PFD generates a first detection signal according to a first divided clock, for controlling the first current source, wherein the first divided clock is generated according to an oscillation clock having an oscillation period. The second current source provides a second current. The second PFD generates a second detection signal according to a second divided clock, for controlling the second current source. The divided clock controller controls the second divided clock based on a variable delay relative to the first divided clock, wherein the variable delay is an integer times the oscillation period.

A signal generating circuit includes a control voltage setting unit (CVSU) configured to set a control voltage for a chirp signal using voltage-frequency characteristics indicating characteristics of an output frequency versus voltage; a VCO configured to alter the frequency of its output signal by the control voltage; a quadrature demodulator configured to perform quadrature demodulation of the output signal of the VCO to generate an inphase signal and a quadrature signal orthogonal to each other; and a frequency detector configured to detect the frequency of the output signal of the VCO on the basis of the inphase signal and quadrature signal. The CVSU corrects the control voltage by using the voltage-frequency characteristics derived from relationships between the control voltage and the frequency of the output signal of the VCO. The VCO generates the chirp signal based on the control voltage corrected by the CVSU.

Aspects of the disclosure relate to a ring oscillator (RO) frequency divider configured to frequency divide an input clock by a programmable divider ratio to generate an output clock. In this regard, the RO frequency divider receives the input clock, enables each of a ring of N cascaded inverter stages substantially one at a time in response to the input clock; and outputs a second clock from an output of one of the ring of N cascaded inverter stages. In one aspect, each stage includes a p-channel metal oxide semiconductor field effect transistor (PMOS FET) coupled in series with an n-channel metal oxide semiconductor field effect transistor (NMOS FET). In another, each stage includes two PMOS FETs and an NMOS FET.

Aspects of the disclosure relate to a ring oscillator (RO) frequency divider configured to frequency divide an input clock by a programmable divider ratio to generate an output clock. In this regard, the RO frequency divider receives the input clock, enables each of a ring of N cascaded inverter stages substantially one at a time in response to the input clock; and outputs a second clock from an output of one of the ring of N cascaded inverter stages. In one aspect, each stage includes a p-channel metal oxide semiconductor field effect transistor (PMOS FET) coupled in series with an n-channel metal oxide semiconductor field effect transistor (NMOS FET). In another, each stage includes two PMOS FETs and an NMOS FET.

A fractional-N phase locked loop (PLL) and a sliced charge pump (CP) control method thereof are provided. The fractional-N PLL includes a first current source, a first phase frequency detector (PFD), a second current source, a second PFD, and a divided clock controller. The first current source provides a first current. The first PFD generates a first detection signal according to a first divided clock, for controlling the first current source, wherein the first divided clock is generated according to an oscillation clock having an oscillation period. The second current source provides a second current. The second PFD generates a second detection signal according to a second divided clock, for controlling the second current source. The divided clock controller controls the second divided clock based on a variable delay relative to the first divided clock, wherein the variable delay is an integer times the oscillation period.

A memory device includes a clock input configured to receive a clock from a host device. The memory device also includes a command input configured to receive command and address bits from the host device. The memory device further includes multiple die stacked in a three-dimensional stack. A first die of the plurality of die includes a first plurality of memory cells and first local control circuitry. The first local circuitry includes division circuitry configured to receive the clock from the clock input, generate a divided clock having a lower frequency than that of the clock, and generate multiple clocks from the divided clock with each of the multiple clocks having a lower frequency than the divided clock. The memory device also includes one or more transmitters configured to transmit the multiple clocks using a inter-die interconnects between the multiple die.

A memory device includes a clock input configured to receive a clock from a host device. The memory device also includes a command input configured to receive command and address bits from the host device. The memory device further includes multiple die stacked in a three-dimensional stack. A first die of the plurality of die includes a first plurality of memory cells and first local control circuitry. The first local circuitry includes division circuitry configured to receive the clock from the clock input, generate a divided clock having a lower frequency than that of the clock, and generate multiple clocks from the divided clock with each of the multiple clocks having a lower frequency than the divided clock. The memory device also includes one or more transmitters configured to transmit the multiple clocks using a inter-die interconnects between the multiple die.

A reference sampling Type-I fractional-N PLL directly samples the reference clock and therefore does not use a reference buffer. Here, a phase-detector is a passive sampling switch which neither consumes any power nor generates any noise. Therefore, all the major contributors of in-band phase-noise are eliminated by the reference sampling Type-I fractional-N divider. A double sampling phase-detector with a switched-capacitor passive voltage interpolator circuit is used to achieve fractional-N output. To achieve a high resolution of the voltage interpolator or the switched capacitor, a sigma-delta modulator is used.