Methods and systems for split voltage domain transmitter circuits are disclosed and may include a two-branch output stage including a plurality of CMOS transistors, each branch of the two-branch output stage comprising two stacked CMOS inverter pairs from among the plurality of CMOS transistors; the two stacked CMOS inverter pairs of a given branch being configured to drive a respective load, in phase opposition to the other branch; and a pre-driver circuit configured to receive a differential modulating signal and output, to respective inputs of the two stacked CMOS inverters, two synchronous differential voltage drive signals having a swing of half the supply voltage and being DC-shifted by half of the supply voltage with respect to each other. The load may include a series of diodes that are driven in differential mode via the drive signals. An optical signal may be modulated via the diodes.

A semiconductor package including: a chip having a first surface; a mold having a first surface and a second surface configured to encapsulate the chip; a conduction structure electrically connecting the first surface and the second surface of the mold; an optical device arranged on the first surface of the mold to be electrically connected to the conduction structure; a wiring pattern configured to electrically connect the conduction structure and a pad formed on the first surface of the chip, and perform electrical connection in the semiconductor package; and an external connection terminal configured to electrically connect the semiconductor package to the outside.

Methods and systems for split voltage domain receiver circuits are disclosed and may include amplifying complementary received signals in a plurality of partial voltage domains. The signals may be combined into a single differential signal in a single voltage domain. Each of the partial voltage domains may be offset by a DC voltage from the other partial voltage domains. The sum of the partial domains may be equal to a supply voltage of the integrated circuit. The complementary signals may be received from a photodiode. The amplified received signals may be amplified via stacked common source amplifiers, common emitter amplifiers, or stacked inverters. The amplified received signals may be DC coupled prior to combining. The complementary received signals may be amplified and combined via cascode amplifiers. The voltage domains may be stacked, and may be controlled via feedback loops. The photodetector may be integrated in the integrated circuit.

A system for connecting a fiber optic cable to a laminate has a clip which attaches to a cover on the circuit board. The clip supports ferrules which are connected to a photonic device on the board. The clip has a backplane which supports retainers which hold the ferrules. The clip also has mating attachments for connecting to the cover. The cover additionally serves as a heat dissipater, which can include heat from the photonic device. An adapter is connected to the cover and receives the ferrules supported by the clip. The adapter connects to a standard connector, such as an LC connector. The adapter can be positioned at the edge of the laminate, or can be attached at an angle extending from an interior region of a circuit board to which the laminate is mounted.

A semiconductor package including: a chip including a pad; an optical device including a pad; a mold configured to encapsulate the optical device and the chip; a wiring pattern configured to electrically connect the optical device and the chip; and an external connection terminal configured to electrically connect the semiconductor package to the outside. The chip includes at least one of: an amplifier circuit configured to process an electrical signal supplied from the optical device; and a driver circuit configured to supply the electrical signal to the optical device.

Methods and systems for split voltage domain receiver circuits are disclosed and may include amplifying complementary received signals in a plurality of partial voltage domains. The signals may be combined into a single differential signal in a single voltage domain. Each of the partial voltage domains may be offset by a DC voltage from the other partial voltage domains. The sum of the partial domains may be equal to a supply voltage of the integrated circuit. The complementary signals may be received from a photodiode. The amplified received signals may be amplified via stacked common source amplifiers, common emitter amplifiers, or stacked inverters. The amplified received signals may be DC coupled prior to combining. The complementary received signals may be amplified and combined via cascode amplifiers. The voltage domains may be stacked, and may be controlled via feedback loops. The photodetector may be integrated in the integrated circuit.

A system for passive alignment of fibers to an interface of a photonic integrated circuit (PIC) includes an input frame, an actuator, and an output frame. The actuator arranged to apply force along a force axis to the input frame. The output frame including a tip for picking up a plate and transferring the force thereto, the output frame being connected to the input frame such that the output frame may tilt relative to the input frame and the output frame is elastically biased relative to the input frame into a position wherein the tip is aligned on the force axis.

A fiber alignment or fiberposer device enables the passive alignment of one or more optical fibers to a photonic integrated circuit (PIC) device using mating hard-stop features etched into the two devices. Accordingly, fiber grooves can be provide separate from the electrical and optical elements, and attached to the PIC with sub-micron accuracy. Fiberposers may also include a hermetic seal for a laser or other device on the PIC. All of these features significantly reduce the typical cost of an actively aligned optical device sealed in an hermetic package.

A light-emitting device includes a board, a light-emitting element mounted on a surface of the board, a support member on which the board is placed, and a cover having a plate shaped main cover body covering the light-emitting element and a tubular portion which receives a light guide body that guides light emitted from the light-emitting element. The main cover body includes a base, a protrusion protruding from the base toward the board, and a ridge disposed on a protruded end of the protrusion. A step is formed by the protrusion and the ridge, and the protrusion and the ridge extend in a same direction along the base.

A semiconductor package structure and a method of manufacturing a semiconductor package structure are provided. The semiconductor package structure includes a first electronic device and a second electronic device. The first electronic device has an active surface and a lateral surface angled with the active surface, and the lateral surface includes a first portion and a second portion that is non-coplanar with the first portion. The second electronic device is disposed on the active surface of the first electronic device.