Abstract: Apparatus and methods for fractional-N synthesizer phase-locked loops with multi-phase oscillators are provided. In certain configurations, a fractional-N PLL includes a time-to-digital converter (TDC), a digital loop filter, a multi-phase oscillator, and fractional division circuitry. The multi-phase oscillator includes multiple taps used to generate multiple clock signal phases that are provided to the fractional division circuitry to reduce the fractional-N PLL's quantization error. The fractional division circuitry includes a tap error correction circuit for compensating for errors in tap positions of the multi-phase oscillator. By including the tap error correction circuit, the phase noise and/or jitter performance of the fractional-N PLL can be enhanced.

Abstract: Apparatus and methods for fractional-N synthesizer phase-locked loops with multi-phase oscillators are provided. In certain configurations, a fractional-N PLL includes a time-to-digital converter (TDC), a digital loop filter, a multi-phase oscillator, and fractional division circuitry. The multi-phase oscillator includes multiple taps used to generate multiple clock signal phases that are provided to the fractional division circuitry to reduce the fractional-N PLL's quantization error. The fractional division circuitry includes a tap error correction circuit for compensating for errors in tap positions of the multi-phase oscillator. By including the tap error correction circuit, the phase noise and/or jitter performance of the fractional-N PLL can be enhanced.

Abstract: Provided herein are apparatus and methods for reducing supply noise conversion to phase noise. In certain configurations, voltage controlled elements such as varactors are used to control a VCO output frequency. A VCO transfer function relating supply voltage noise to a common node of a varactor gives rise to a transfer function of value a representing a push coefficient. An intentional amount of supply noise can be added to a tuning voltage by injecting it at a tuning port of the VCO. By splitting an integration capacitance in a loop filter, an integration capacitance can be divided among a capacitor divider to create a transfer function of value ? representing a compensating coefficient. The injected noise from the capacitor divider can reduce VCO pushing by canceling the value ?. When the value ? is set equal to the value ?, the VCO pushing can be reduced to within the estimation or measurement accuracy of the value ?.

Abstract: A CMOS differential twisted-pair driver which utilizes CMOS switches and current sources advantageously. No alternative power supply is required, the switches do not have to be low impedance and the device is low power. The preferred embodiment driver further limits signal overshoot and common mode energy. The signal transmission facility is bi-directional so an off state is provided. It is doubly terminated to provide for symmetry, improved bandwidth and reduces reflective signal noise. The double termination also provides for faster rise and fall times which reduces the systems sensitivity to receiver offset.

Abstract: The delay line separator extracts a clock signal from a combined data/clock encoded signal received over a serial data bus, despite the presence of significant duty cycle distortion. Such distortion affects the width of symbols within received data packets but does not affect the timing between successive rising edges within the received pulse string. To extract the chock signal from the distorted signal, the separator exploits a pre-filter circuit which generates 2 -nanosecond pulses synchronized with each rising edge in the received signal. A 20-nanosecond pulse train is transmitted down a delay line having twelve delay elements. Circuits are connected to every other delay element within the delay line for generating 10-nanosecond pulses, synchronized with each rising edge of the pulse train. Outputs from the circuits are combined using an OR gate to yield a 10-nanosecond clock signal.

Abstract: A differential-to-CMOS level signal converter which receives a first differential signal having a small amplitude difference between the binary signals. The differential-to-CMOS level converter amplifies and level shifts the binary differential signal and outputs a single-ended CMOS level signal suitable for use by digital CMOS logic. A circuit for biasing the differential-to-CMOS level converter is coupled to the level shifting circuitry.

Abstract: In a computer bus arrangement in which a plurality of nodes are interconnected by communication links, control signals are exchanged between the nodes concerning the transmission rate of a data message to be transmitted and the reception rate capability of the nodes. The data message is passed to those nodes which have a reception rate capability which matches or exceeds the transmission rate associated with the message. The other nodes receive a mock data message at a rate within their capability. In order to aid in synchronization within the bus arrangement, the duration of the mock data message is the same as the data message received by the other nodes, even though they are transmitted at different rates.

Abstract: The class AB amplifier is configured to provide low quiescent current while achieving high internal switching rates. The buffer is connected to a large external capacitance which provides external compensation. The amplifier includes an input stage which converts differential voltages to current. An output stage provides an output current and also provides a feedback current into the input stage. A biasing network provides voltage for biasing various nodes within the amplifier. Cross-coupling is provided within the output stage for achieving a low quiescent current. A pair of current limiting circuits, one for p-channel element and another for n-channel elements, is also provided.

Abstract: The de-skewer utilizes a delay line to generate a set of delayed versions of an input clock signal. A bank of flip-flops compares pulses within the delayed clock signals to a synchronization pulse provided within an input data signal. A detector receives outputs from the flip-flops and selects the delayed clock signal having the least amount of skew based on the values of the output from the flip-flops. A multiplexer outputs the selected delayed clock. The de-skewer provides a simple, open-loop circuit for eliminating skew between parallel transmission paths. The de-skewer is ideally suited for eliminating skew from sources which do not vary significantly as a function of time. In particular, the de-skewer is well-suited for use in a data transmission system providing short bursts of high data rate transmissions. A double-edged de-skewer is also described which is capable of generating a pair of clock signals for use in eliminating duty cycle distortion.

Abstract: The level shifter provides a selective voltage level shift to a common mode signal level on a twisted pair signal line. The level shift is selectively performed based upon the input level of the common mode voltage. The level shifter is advantageously employed in a low voltage circuit wherein lacking sufficient voltage head room to accommodate a constant common mode level shift. An exemplary embodiment is described wherein the level shifter is employed within a bus transceiver of a bus system employing IEEE P1394 bus protocol. In the exemplary embodiment, the selective level shift is applied only to bus signals occurring during an idle phase and an arbitration phase, with no level shift performed during a data phase.

Abstract: A CMOS differential twisted-pair driver which utilizes CMOS switches and current sources advantageously. No alternative power supply is required, the switches do not have to be low impedance and the device is low power. The preferred embodiment driver further limits signal overshoot and common mode energy. The signal transmission facility is bi-directional so an off state is provided. It is doubly terminated to provide for symmetry, improved bandwidth and reduces reflective signal noise. The double termination also provides for faster rise and fall times which reduces the systems sensitivity to receiver offset.

Abstract: An adaptive data separator for detecting systematic differences between the arrivals of the rising and falling edges of a digital signal and for compensating for the difference. Data packets from a transmission source are prefixed with two data bits of known values. The data separator is also supplied with four clock signals per bit, one corresponding to an ideal rising edge and three following every 5 nanoseconds. The two prefix bits preceding a data packet are then sampled at each of the clock signals. Since all information in a given data packet undergoes the same systematic distortion, the logic of the adaptive data separator can determine the optimum clock signal to use in sampling each bit of data for the packet. Through several multiplexers the incoming data is then clocked to the optimal clock signal for sampling.

Abstract: The delay line separator extracts a clock signal from a combined data/clock encoded signal received over a serial data bus, despite the presence of significant duty cycle distortion. Such distortion affects the width of symbols within received data packets but does not affect the timing between successive rising edges within the received pulse string. To extract the clock signal from the distorted signal, the separator exploits a pre-filter circuit which generates 20-nanosecond pulses synchronized with each rising edge in the received signal. A 20-nanosecond pulse train is transmitted down a delay line having twelve delay elements. Circuits are connected to every other delay element within the delay line for generating 10-nanosecond pulses, synchronized with each rising edge of the pulse train. Outputs from the circuits are combined using an OR gate to yield a 10-nanosecond clock signal.

Abstract: The present invention provides a method and apparatus for transmitting NRZ data signals across an interface comprising an isolation barrier disposed between two devices interconnected via a bus. The apparatus comprises a signal differentiator for receiving an NRZ data signal and outputting a differentiated signal. A driver comprising a tri-state gate has as a first input the data signal and as a second input the differentiated signal for enabling the tri-state gate when the differentiated signal is high. A bias voltage is applied to an output of the tri-state gate to derive as output a transmission signal for transmission via the bus across the interface between the two devices.

Abstract: The present invention provides a bus transceiver incorporating a high speed, binary transfer mode for the half-duplex transfer of data signals with a ternary control transfer mode having a full duplex dominant logic transmission scheme for the full duplex transfer of control signals. In one embodiment of the present invention, the above-noted transfer modes are implemented in a bus architecture which includes at least a first communications node coupled to a second communications node via a twisted pair, serial bus. Each node comprises first transceiver and second transceivers having a differential driver for driving on the bus signal states comprising first and second signal states having equal current amplitudes opposite in sign and a third signal state having approximately a zero current amplitude, a high speed binary receiver for receiving high speed data signals during data transfer phases and a ternary receiver for receiving control signals during control transfer phases.

Abstract: An extended range logic circuit is activated to decrease the settling time and prevent slip, when phase difference of two signals being compared by a phase comparator reaches a slip point. The circuit provides error correction signals to compensate for the phase correction at a much faster rate when the phase error reaches a predetermined point, which is proximate to the slip point. However, the extended capture range circuit in only active during the lock acquisition. After lock is achieved the extended capture range logic is disabled, to provide better jitter performance.