Abstract: A programmable spread spectrum clock generator (SSCG) reduces electromagnetic interference by spreading the frequency bandwidth of an output signal. The rate at which the frequency of the output signal changes, as well as other aspects of the output signal, are software programmable. The programmable SSCG receives a periodic signal whose cycles have substantially identical periods and outputs the output signal whose cycles have periods that vary smoothly over a plurality of cycles of the periodic signal. The programmable SSCG generates a control signal using the periodic signal. The programmable SSCG includes a variable delay element that generates the output signal by delaying the periods of the periodic signal based on the magnitude of the control signal. The output signal is generated without using a phase locked loop. Moreover, successive cycles of the output signal rarely have identical periods.

Abstract: A programmable spread spectrum clock generator (SSCG) reduces electromagnetic interference by spreading the frequency bandwidth of an output signal. The rate at which the frequency of the output signal changes, as well as other aspects of the output signal, are software programmable. The programmable SSCG receives a periodic signal whose cycles have substantially identical periods and outputs the output signal whose cycles have periods that vary smoothly over a plurality of cycles of the periodic signal. The programmable SSCG generates a control signal using the periodic signal. The programmable SSCG includes a variable delay element that generates the output signal by delaying the periods of the periodic signal based on the magnitude of the control signal. The output signal is generated without using a phase locked loop. Moreover, successive cycles of the output signal rarely have identical periods.

Abstract: A programmable spread spectrum clock generator (SSCG) reduces electromagnetic interference by spreading the frequency bandwidth of an output signal. The rate at which the frequency of the output signal changes, as well as other aspects of the output signal, are software programmable. The programmable SSCG receives a periodic signal whose cycles have substantially identical periods and outputs the output signal whose cycles have periods that vary smoothly over a plurality of cycles of the periodic signal. The programmable SSCG generates a control signal using the periodic signal. The programmable SSCG includes a variable delay element that generates the output signal by delaying the periods of the periodic signal based on the magnitude of the control signal. The output signal is generated without using a phase locked loop. Moreover, successive cycles of the output signal rarely have identical periods.

Abstract: Presence or absence of a differential clock is detected. The voltage of each differential clock line is compared to the common-mode voltage and integrated over time by a capacitor. The capacitor is discharged during the portions of the clock cycle that the differential line is over the common-mode voltage. If the clock stops pulsing the capacitor is charged by a current source to activate a clock-loss signal. The clock-loss detector is ideal for high-frequency operation since each differential clock line is applied to only one transistor gate. The common-mode voltage generates a bias voltage for a differential amplifier that receives the true and complement differential clock lines. Diodes prevent capacitor charging by reverse current flow from the differential amplifier when the clock is inactive. The averaged peak voltage or envelope of the differential input signals is detected.

Abstract: A phase-locked loop (PLL) keeps tracking a reference clock when a frequency offset is introduced. The PLL has primary and secondary PLL loops. A digital-to-analog converter (DAC) generates a current that is passed through an offset resistor to generate an offset voltage. An op amp is inserted in the primary loop between a filter capacitor and a voltage-controlled oscillator (VCO). The offset resistor is coupled between the inverting input of the op amp and the op amp's output. When the DAC offset occurs, the voltage to the VCO and the frequency of the primary loop change and the primary loop loses tracking of the reference clock. The secondary loop keeps tracking the reference clock during the DAC offset while the primary loop is open. Then the output clock of the secondary loop is applied as the feedback clock to the phase comparator of the primary loop.

Abstract: A clock generator uses two PLL loops and a digital-to-analog converter (DAC) to generate a variable output frequency from a single fixed-frequency reference clock. Each PLL loop receives the reference clock and phase-compares it with a feedback clock. The feedback clock in one loop is slightly faster in frequency than the feedback clock in the second loop. The input voltages to voltage-controlled oscillators (VCOs) in the two loops thus vary slightly. A DAC is connected between the two VCO inputs. The DAC's two reference-voltage inputs are connected to these VCO inputs. The DAC's output voltage is selected from within the voltage range between the two VCO voltages by a digital code-word input to the DAC. The DAC's output voltage is input to a final VCO that generates the variable output frequency. The output frequency is varied by selecting the digital code-word input to the DAC.

Abstract: A power-down signal is encoded into a differential pair of lines between two chips. When the differential transmitter powers down, it enters a high-impedance state and floats the differential lines. A shunt resistor between a pair of differential lines equalize the voltages on the differential lines so they float to a same voltage when a differential transmitter is disabled and enters a high-impedance state. The condition of equal voltages on the differential lines is detected by an equal-voltage detector that generates a power-down signal when the differential lines are at equal voltages for a period of time. The period of time can be greater than the cross-over time during normal switching to prevent false power-downs during normal switching. Standard differential drivers can signal power-down using the high-impedance state, which is detected by equal voltages on the differential lines. A sensitive dual-differential amplifier and a simpler detector are disclosed.

Abstract: A voltage-controlled crystal oscillator (VCXO) has variable load capacitors on the crystal nodes. The variable load capacitors are p-channel or n-channel transistors with their source and drain nodes connected to a crystal node. The gates are driven by an input voltage that is generated from a full-swing control voltage by a voltage conversion circuit. The input voltage has a half-swing of only half of the power-supply voltage, or VDD/2. The input voltage driving n-channel capacitors swings from VDD to VDD/2, which is just above the source voltage of VDD/2 on the crystal node and ensures that the n-channel capacitors remain on for most of the range. A series of resistors can divide the input voltage into a series of differing voltages that drive gates of multiple n-channel capacitors that have their source/drains connected in parallel to the crystal node. Capacitance increases as an n-channel capacitor channel turns on.

Abstract: A power-down signal is encoded into a differential pair of lines between two chips. When the differential transmitter powers down, it enters a high-impedance state and floats the differential lines A shunt resistor between a pair of differential lines equalize the voltages on the differential lines so they float to a same voltage when a differential transmitter is disabled and enters a high-impedance state. The condition of equal voltages on the differential lines is detected by an equal-voltage detector that generates a power-down signal when the differential lines are at equal voltages for a period of time. The period of time can be greater than the cross-over time during normal switching to prevent false power-downs during normal switching. Standard differential drivers can signal power-down using the high-impedance state, which is detected by equal voltages on the differential lines. A sensitive dual-differential amplifier and a simpler detector are disclosed.

Abstract: When the clock is stopped during a power-down mode, a clock duty-cycle detector asserts a power-down signal. The clock input is filtered to produce an average clock voltage over several clock periods. The average clock voltage is compared to an upper reference voltage to determine when the clock's duty cycle (high pulse-width percent) is above an upper limit. The average clock voltage is also compared to a lower reference voltage to determine when the clock's duty cycle is below a lower limit. When the clock's duty cycle is above the upper limit or below the lower limit the power-down signal is activated by logic. The logic disables the power-down signal when the clock's duty cycle is between the upper and lower limits. High-frequency clock glitches do not falsely trigger a power-up, since glitches are usually narrow and not sufficiently wide to reach the lower limit.

Abstract: A voltage-variable capacitor is constructed from a metal-oxide-semiconductor transistor. The transistor source has at least two contacts that are biased to different voltages. The source acts as a resistor with current flowing from an upper source contact to a lower source contact. The gate-to-source voltage varies as a function of the position along the source-gate edge. A critical voltage is where the gate-to-source voltage is equal to the transistor threshold. A portion of the source has source voltages above the critical voltage and no conducting channel forms under the gate. Another portion of the source has source voltages below the critical voltage, and thus a conducting channel forms under the gate for this portion of the capacitor. By varying either the gate voltage or the source voltages, the area of the gate that has a channel under it is varied, varying the capacitance. Separate source islands eliminate source current.

Abstract: A clock generator uses two PLL loops and a variable resistor to generate a variable output frequency from a single fixed-frequency reference clock. Each PLL loop receives the reference clock and phase-compares it with a feedback clock. The feedback clock in one loop is slightly faster in frequency than the feedback clock in the second loop. The input voltages to voltage-controlled oscillators (VCOs) in the two loops thus vary slightly. A variable resistor is connected between the two inputs to the VCOs. The variable resistor has a center tap that can be selected from locations along the variable resistor. The center tap voltage is input to a final VCO that generates the variable output frequency. The output frequency is varied by selecting the center tap's location along the variable resistor. The variable resistor can be constructed from a series of sub-resistors with the center-tap location chosen by select transistors acting as a multiplexer.