Abstract: Embodiments disclosed herein include electronic packages and methods of forming electronic packages. In an embodiment, the electronic package comprises a package substrate, a die coupled to the package substrate, a photonics integrated circuit (PIC) coupled to the die, and a fiber array unit (FAU) optically coupled to the PIC. In an embodiment, the FAU has a base with a first width and a protrusion with a second width that is smaller than the first width.

Abstract: Embodiments disclosed herein include optoelectronic systems and methods of forming such systems. In an embodiment, an optoelectronic system comprises a first substrate, a second substrate over the first substrate, a micro-ring resonator (MRR) over the second substrate, a heater integrated into the MRR, a cladding over the MRR, an opening through the first substrate and the second substrate to expose a bottom surface of the MRR, and a base spanning across the opening.

Abstract: Embodiments disclosed herein include an on-cavity photonic integrated circuit (OCPIC). In an embodiment, the OCPIC comprises a laser transmitter, that comprises a row with four bumps, and a micro-ring resonator (MRR) in the row between a first bump and a second bump of the four bumps. In an embodiment, a cavity is below the MRR, where a diameter of the cavity is substantially equal to a spacing between the first bump and the second bump.

Abstract: Embodiments disclosed herein include an optoelectronic system. In an embodiment, the optoelectronic system comprises a first substrate, a second substrate over the first substrate, and a micro-ring resonator (MRR) over the second substrate. In an embodiment, a heater is integrated into the MRR, a cladding is over the MRR, and a temperature sensor is over the MRR in the cladding.

Abstract: An integrated circuit having a transmitter is provided. The transmitter may include a serializer, a driver, and an associated calibration circuit. The calibration circuit may include a detector and a control circuit. The control circuit may output a first control signal for selectively configuring the serializer to inject test data and may also output a second control signal for selectively inverting the input polarity of the detector. The control circuit may configure the transmitter in at least four different modes by adjusting the first and second control signals. In each of the four modes, the control circuit may sweep a clock duty cycle correction (DCC) setting that controls only the serializer until the detector flips. Codes generated in this way may be used to compute calibrated settings that mitigates both clock and data duty cycle distortion for the transmitted data.

Abstract: The present disclosure provides apparatus and methods for the calibration of analog circuitry on an integrated circuit. One embodiment relates to a method of calibrating analog circuitry within an integrated circuit. A microcontroller that is embedded in the integrated circuit is booted up. A reset control signal is sent to reset an analog circuit in the integrated circuit, and a response signal for the analog circuit is monitored by the microcontroller. Based on the response signal, a calibration parameter for the analog circuit is determined, and the analog circuit is 10 configured using the calibration parameter. Other embodiments, aspects and features are also disclosed.

Abstract: An integrated circuit having a transmitter is provided. The transmitter may include a serializer, a driver, and an associated calibration circuit. The calibration circuit may include a detector and a control circuit. The control circuit may output a first control signal for selectively configuring the serializer to inject test data and may also output a second control signal for selectively inverting the input polarity of the detector. The control circuit may configure the transmitter in at least four different modes by adjusting the first and second control signals. In each of the four modes, the control circuit may sweep a clock duty cycle correction (DCC) setting that controls only the serializer until the detector flips. Codes generated in this way may be used to compute calibrated settings that mitigates both clock and data duty cycle distortion for the transmitted data.

Abstract: A computer-implemented method includes receiving a first circuit design for an integrated circuit device, determining when multiple power-drawing events are to occur at substantially the same time via one or more circuitry components of the integrated circuit device, which would have a disruptive effect on a power distribution network of the integrated circuit device, based on the first circuit design, and generating logic that schedules the more than one event so that the more than one event do not occur simultaneously. The logic is included in an event sequencer. The method also includes inserting the event sequencer into the first circuit design during compilation to create a second circuit design and outputting the second circuit design to be implemented on the integrated circuit device.

Abstract: The present disclosure provides apparatus and methods for the calibration of analog circuitry on an integrated circuit. One embodiment relates to a method of calibrating analog circuitry within an integrated circuit. A microcontroller that is embedded in the integrated circuit is booted up. A reset control signal is sent to reset an analog circuit in the integrated circuit, and a response signal for the analog circuit is monitored by the microcontroller. Based on the response signal, a calibration parameter for the analog circuit is determined, and the analog circuit is 10 configured using the calibration parameter. Other embodiments, aspects and features are also disclosed.

Abstract: The present disclosure provides apparatus and methods for the calibration of analog circuitry on an integrated circuit. One embodiment relates to a method of calibrating analog circuitry within an integrated circuit. A microcontroller that is embedded in the integrated circuit is booted up. A reset control signal is sent to reset an analog circuit in the integrated circuit, and a response signal for the analog circuit is monitored by the microcontroller. Based on the response signal, a calibration parameter for the analog circuit is determined, and the analog circuit is configured using the calibration parameter. Other embodiments, aspects and features are also disclosed.

Abstract: A computer-implemented method includes receiving a first circuit design for an integrated circuit device, determining when multiple power-drawing events are to occur at substantially the same time via one or more circuitry components of the integrated circuit device, which would have a disruptive effect on a power distribution network of the integrated circuit device, based on the first circuit design, and generating logic that schedules the more than one event so that the more than one event do not occur simultaneously. The logic is included in an event sequencer. The method also includes inserting the event sequencer into the first circuit design during compilation to create a second circuit design and outputting the second circuit design to be implemented on the integrated circuit device.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.

Abstract: Systems and methods for reducing jitter due to power supply noise in an integrated circuit by drawing additional current. The additional current causes the total current to generally have a frequency higher than a resonant frequency of the integrated circuit and/or a power distribution network of the integrated circuit. A power distribution network may supply power to components of an integrated circuit, and data driver circuitry may draw first current to drive a serial data signal generated from a parallel data signal. Compensation circuitry may receive the parallel data signal and draw second current at times when the compensation circuitry determines data driver circuitry is not drawing the first current based on the parallel data signal, thereby causing a net of the first and second current to be higher than a resonant frequency range of the integrated circuit device and/or a component of the integrated circuit device.

Abstract: A driver circuit drives data to an output based on an input data signal in a transmission mode. The driver circuit includes transistors. A comparator generates a comparison output in a calibration mode based on a reference signal and a signal at the output of the driver circuit. A calibration control circuit adjusts an equivalent resistance of the transistors in the driver circuit based on the comparison output in the calibration mode. The equivalent resistance of the transistors in the driver circuit can be adjusted to support the transmission of data according to multiple different data transmission protocols using transmission links having different characteristic impedances. The equivalent resistance of the transistors in the driver circuit can also be adjusted to compensate for resistance in the package routing conductors and/or to compensate for parasitic resistance.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.

Abstract: A driver circuit drives data to an output based on an input data signal in a transmission mode. The driver circuit includes transistors. A comparator generates a comparison output in a calibration mode based on a reference signal and a signal at the output of the driver circuit. A calibration control circuit adjusts an equivalent resistance of the transistors in the driver circuit based on the comparison output in the calibration mode. The equivalent resistance of the transistors in the driver circuit can be adjusted to support the transmission of data according to multiple different data transmission protocols using transmission links having different characteristic impedances. The equivalent resistance of the transistors in the driver circuit can also be adjusted to compensate for resistance in the package routing conductors and/or to compensate for parasitic resistance.

Abstract: One embodiment relates to an integrated circuit including multiple PMA modules, a plurality of multiple-purpose PLLs, multiple reference clock signal inputs, and a programmable clock network. Another embodiment relates to a fracture-able PLL circuit. The fracture-able PLL circuit includes a first phase-locked loop circuit generating a first frequency output, a second phase-locked loop circuit; arranged to generate a second frequency output, and a plurality of shared output resources. Reconfigurable circuitry is arranged so that either of the first and second frequency outputs is receivable by each of the plurality of shared output resources. Another embodiment relates to an integrated circuit including a first strip of PLL circuits on a first side of the integrated circuit, and a second strip of PLL circuits on a second side of the integrated circuit which is opposite from the first side. Other embodiments and features are also disclosed.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.

Abstract: A transceiver system with reduced latency uncertainty is described. In one implementation, the transceiver system has a word aligner latency uncertainty of zero. In another implementation, the transceiver system has a receiver-to-transmitter transfer latency uncertainty of zero. In yet another implementation, the transceiver system has a word aligner latency uncertainty of zero and a receiver-to-transmitter transfer latency uncertainty of zero. In one specific implementation, the receiver-to-transmitter transfer latency uncertainty is eliminated by using the transmitter parallel clock as a feedback signal in the transmitter phase locked loop (PLL). In one implementation, this is achieved by optionally making the transmitter divider, which generates the transmitter parallel clock, part of the feedback path of the transmitter PLL.

Abstract: Systems and methods are provided for adjusting gain of a receiver. Adaptation circuitry is operable to identify, based on a matrix representation of a receiver's output generated from horizontal and vertical sweeps of the receiver's output, an eye opening of the receiver's output. The adaptation circuitry is also operable to determine whether a size of the eye opening needs to be changed. When it is determined that the size of the eye opening needs to be changed, the adaptation circuitry is operable to generate a digital signal to change a gain setting of the receiver. When the signal at the receiver's output is under-equalized, the AC gain of the receiver is increased. When the signal at the receiver's output is over-equalized, the AC gain of the receiver is decreased.