Abstract: Various aspects of the subject technology relate to systems, methods, and machine-readable media for DDR reference voltage training. The method includes receiving a data stream, the data stream including pulses generated from a reference voltage in relation to a voltage input logic low and a voltage input logic high of an input stream. The method also includes receiving a clock signal, the clock signal including an in-phase signal and a quadrature-phase signal, the in-phase signal orthogonal to the quadrature-phase signal. The method also includes utilizing the in-phase signal and the quadrature-phase signal of the clock signal in relation to the data stream to obtain a stream of in-phase samples and a stream of quadrature-phase samples. The method also includes adjusting the reference voltage based on a relationship of the stream of in-phase samples to the stream of quadrature-phase samples.

Abstract: The present disclosure relates to a process for producing high-purity acrylic acid using a dividing wall distillation column and in some instances using water as an entrainer and azeotroping agent. This disclosure provides a process for separating acrylic acid from recovered feed streams which comprise saturated organic acids including propionic acid. The resulting acrylic acid product is of sufficient purity to produce acrylate esters and high molecular weight acrylic acid polymers.

Abstract: The present disclosure relates to a process for producing high-purity acrylic acid using a dividing wall distillation column and in some instances using water as an entrainer and azeotroping agent. This disclosure provides a process for separating acrylic acid from recovered feed streams which comprise saturated organic acids including propionic acid. The resulting acrylic acid product is of sufficient purity to produce acrylate esters and high molecular weight acrylic acid polymers.

Abstract: Processes and systems for separating a mixture of three or more chemical components into multiple product streams each enriched in one of the components are provided herein. In some aspects, the present invention relates to processes for the separation of a chemical mixture including at least a heavy key component, an intermediate key component, and a light key component to form a product stream enriched in the light key component, a product stream enriched in the intermediate key component, and a product stream enriched in the heavy key component. Systems described herein may include one or more thermally coupled distillation columns including, for example, a dividing wall column, or a plurality of distillation columns arranged in a thermally integrated configuration.

Abstract: Processes and systems for separating a mixture of three or more chemical components into multiple product streams each enriched in one of the components are provided herein. In some aspects, the present invention relates to processes for the separation of a chemical mixture including at least a heavy key component, an intermediate key component, and a light key component to form a product stream enriched in the light key component, a product stream enriched in the intermediate key component, and a product stream enriched in the heavy key component. Systems described herein may include one or more thermally coupled distillation columns including, for example, a dividing wall column, or a plurality of distillation columns arranged in a thermally integrated configuration.

Abstract: Processes and systems for separating a mixture of three or more chemical components into multiple product streams each enriched in one of the components are provided herein. In some aspects, the present invention relates to processes for the separation of a chemical mixture including at least a heavy key component, an intermediate key component, and a light key component to form a product stream enriched in the light key component, a product stream enriched in the intermediate key component, and a product stream enriched in the heavy key component. Systems described herein may include one or more thermally coupled distillation columns including, for example, a dividing wall column, or a plurality of distillation columns arranged in a thermally integrated configuration.

Abstract: A transfer-hydrogenation process for preparing a carbonyl compound and an alcohol compound comprises the steps of (a) contacting a first carbonyl compound with a first alcohol compound in the presence of a transfer-hydrogenation catalyst in a first reaction zone at conditions effective to form a second carbonyl compound from the first alcohol compound and a second alcohol compound from the first carbonyl compound, and (b) removing the second carbonyl compound from the first reaction zone during step (a). The first carbonyl compound is a saturated aldehyde or ketone, or an ?,?-unsaturated aldehyde or ketone. The first alcohol compound is a primary or secondary alcohol. The second alcohol compound is ?,?-saturated. The transfer-hydrogenation catalyst includes a Group 8 to 11 metal. This process is useful for preparing and higher value alcohols, such as butanol or 2-ethylhexanol, from the corresponding carbonyl compounds by engaging lower alcohol (C2-C4) feedstocks instead of hydrogen (H2).

Abstract: Processes and systems for separating a mixture of three or more chemical components into multiple product streams each enriched in one of the components are provided herein. In some aspects, the present invention relates to processes for the separation of a chemical mixture including at least a heavy key component, an intermediate key component, and a light key component to form a product stream enriched in the light key component, a product stream enriched in the intermediate key component, and a product stream enriched in the heavy key component. Systems described herein may include one or more thermally coupled distillation columns including, for example, a dividing wall column, or a plurality of distillation columns arranged in a thermally integrated configuration.

Abstract: Cyclic acetals can be produced in a reactive distillation apparatus by combining a polyhydroxyl compound and an aldehyde. High concentrations of cyclic acetals are removed as liquid products from the column while water is removed as an overhead vapor stream.

Abstract: A system and method are provided for phase recovery of a signal received by a receiver having digital equalization. A sample acquisition unit periodically acquires a plurality of I and Q samples of the received signal. The sample acquisition unit includes a delay portion to enable selective mutual comparisons between a current I sample ID0, a first preceding I samples ID1, and a second preceding I sample ID2. A transition detection unit generates at least one transition detect signal responsive to the ID1, ID0, and Q samples. The transition detect signal indicates a logic state transition in the received signal between the ID1 and ID0 samples. A transition filtering unit generates an equalization detect signal indicative of excessive equalizing correction of the received signal at the ID0 sample, and selectively passes in response the transition detect signal as a timing output signal.

Abstract: Cyclic acetals can be produced in a reactive distillation apparatus by combining a polyhydroxyl compound and an aldehyde. High concentrations of cyclic acetals are removed as liquid products from the column while water is removed as an overhead vapor stream.

Abstract: An apparatus opto-electronic module that is flexible in design such that components of different types and dimensions can be incorporated into the module without straying from certain mechanical standards requirements is described. Generally, an opto-electronic module of the present invention includes a first substrate that supports an opto-electronic device and thereby the optical port, a second substrate that includes the electrical port, and a flexible connector that electrically connects the first and second substrates. The flexible connector allows for the first substrate and the second substrate to be positioned in various orientations with respect to each other so that optical and electrical components of various sizes can be utilized and still remain in compliance with a set of mechanical standards.

Abstract: The present invention provides a method and mechanism for regenerating the clock signal and recovering the data of a serial bit data stream. According to an embodiment, a circuit for recovering data from a serial bit stream may include a de-serializer configured for reclocking the serial bit stream using at least one reclocking signal, having a frequency with a phase, and de-serializing the serial bit stream into at least two bit streams. The circuit may further include a clock recovery loop filter having a second order filter coupled with the deserializer. The clock recovery loop filter may be configured for determining whether the de-serializer is reclocking the serial bit data stream at an optimum location and for generating at least one control signal to adjust the phase of the frequency of the at least one reclocking signal if the de-serializer is not reclocking the serial bit data stream at the optimum location.

Abstract: A plug device for use during manufacturing and/or testing processes for optoelectronic (OE) devices is described. The plug device has a handle and structures that extend off of the handle to cover “barrels” of an OE device. The plug device prevents contaminating particulates from reacting the lenses and/or the photonic devices within the OE device. The plug device can also be made of a material that transmits light signals so that testing of the OE devices can be easily performed. The plug device can also have a surface to which a pick and place machine can attach itself so that the plug device and a respective optoelectronic device can be easily transported. Overall, the plug device can simplify both the manufacturing and testing processes for OE devices.