Abstract: A paint manufacturing method includes receiving each of a group of fluid prepaints at different inputs of a fluid component mixing system, determining at a computer system a first fluid prepaint ratio, and mixing the fluid prepaints in accordance with the first ratio to form a base paint at an output of the mixing system. A paint manufacturing system includes a computer-controlled prepaint mixing system. The prepaint mixing system includes multiple fluid inputs providing for computer-controllable flow of prepaints into the mixing system. The computer system includes a memory storing software instructions that configured the computer system to receive user input selecting a base paint to be produced, determine a ratio of fluid prepaints needed to produce the base paint, and regulate each fluid flow control to establish, in the determined ratio, a flow of fluid prepaints entering the fluid mixing system.

Abstract: A stuck lock-pin release system for a lock-pin in a cam phaser includes a stuck lock-pin detection module and a stuck lock-pin module that communicates with the stuck lock-pin detection module. The stuck-lock pin detection module periodically determines whether a lock-pin in a cam phaser is in a stuck park condition. When the lock-pin is in the stuck park condition, the stuck lock-pin module alternately biases the cam phaser in a first and second direction until the lock-pin is no longer in the stuck park condition.

Abstract: A useable particulate nepheline syenite having a grain size to provide an Einlehner Abrasive Value of less than about 100 is described. The particulate nepheline syenite is generally free from agglomeration and moisture free. At least 99% of the nepheline syenite particles have a size less than 10 microns. In practice, the nepheline syenite grain size is less than about 5 microns and the distribution profile of the particulate system is generally 4-5 microns.

Abstract: A programmable accumulation module (324) with an embedded register array comprises a crosspoint switch (318), a control interface for receiving a control signal (359), a register array circuit (352), a multiplier module (348) for receiving two input values from the crosspoint switch (318) and multiplying the values, and an adder module (350) for adding an output of the multiplier module (348) with an output of the register array circuit (352). The register array circuit includes a plurality of data registers (356), an input multiplexer (354) for receiving an add result from the adder module and communicating the add result to one of the plurality of data registers (356) according to the control signal, and an output multiplexer (358) for receiving an output value from each of the plurality of data registers (356) and selectively communicating one of the plurality of output values to the adder module (350) according to the control signal.

Abstract: An integrated circuit (102) in communication with a host circuit (104) includes an interconnect bus (344) and a plurality of programmable elements (116-130). Each of the programmable elements (116-130) includes a control interface (354) for receiving a control signal, the control signal causing the memory element (338) to selectively operate in one of a plurality of modes. In a first mode, the memory element (338) communicates stored data to the output port upon receiving the control signal; in a second mode the memory element (338) communicates stored data to the output port upon detecting valid data at the input port; in a third mode the memory element stores a first data value consisting of at least a portion of a single data word received at the input port; and in a fourth mode the memory element (338) stores a second data value consisting of at least a portion of each of two separate input values received at the input port.

Abstract: A system for data processing comprises a host circuit (104) and an integrated circuit (102). The integrated circuit (102) is in communication with the host circuit (104) and the host circuit (104) is external to the integrated circuit (102). The integrated circuit (102) includes a plurality of programmable elements for data processing (300), each programmable element (300) including a host interface (305) for receiving host data and a host control signal from the host, a crosspoint switch (318), and an interpolation module (310). The host data includes a serial stream of input data values. The interpolation module (310) selectively inserts one or more interpolation data values, such as zero, between selected ones of the input data values according to the host control signal, and communicates the input data values and interpolation data values to the crosspoint switch (318).

Abstract: A linear combiner weight memory. Various embodiments of the weight memory provide a weight bank and control logic. The weight bank is operable to couple with a data stream and may include four registers. The first register is operable to store a first in-phase weight value. The second register is operable to store a second in-phase weight value and be written with the second in-phase weight value while the first in-phase weight value is read from the first register. The third register is operable to store a first quadrature weight value. The fourth register is operable to store a second quadrature weight value and be written with the second quadrature weight value while the first quadrature weight value is read from the third register.

Abstract: A system for data processing comprises a host circuit (104) and an integrated circuit (102), the host circuit (104) being external to the integrated circuit (102). The integrated circuit (102) includes a plurality of programming elements (300), each element (300) including a host interface (606) for receiving data and a first control signal from the host circuit (104), a control interface (604) for receiving a second control signal. Each element (300) includes a crosspoint switch (318), and a register array (628) for receiving and storing data from the crosspoint switch (318) according to the first and second control signals, for receiving and storing data from the host interface (606) according to the first and second control signals, and for communicating stored data to the crosspoint switch (318) according to the first and second control signals.

Abstract: An apparatus operable to interface an electronic component with a signal input. The apparatus may generally include a low-ohm resistor and a voltage translator coupled with the low-ohm resistor. The low-ohm resistor is operable to couple with the input to receive an input signal therefrom. The voltage translator is operable to couple with the electronic component and translate the input signal from a first voltage to a second voltage for use by the electronic component. The low-ohm resistor and voltage translator may be positioned by a pick and place assembly machine such that embodiments of the present invention do not require a technician to manually couple and solder the apparatus to the input and electronic component.

Abstract: A programmable element for data processing comprises a crosspoint switch (318), a mathematical operation module (320), and a plurality of data hold modules (604,606). Each of the data hold modules (604,606) receives data from the crosspoint switch (318) and communicates the data to an input of the mathematical operation module (320) such that data arrives at the inputs of the mathematical operation module (320) substantially simultaneously. A first data hold module (604) communicates a first data valid signal to a second data hold module (606) upon receipt of first valid data, and the second data hold module communicates a second data valid signal to the first data hold module upon receipt of second valid data.

Abstract: A system for data processing comprises a host circuit (104) and an integrated circuit (102), the host circuit (104) being external to the integrated circuit (102). The integrated circuit (102) includes a plurality of programming elements (300), each element (300) including a host interface (606) for receiving data and a first control signal from the host circuit (104), a control interface (604) for receiving a second control signal. Each element (300) includes a crosspoint switch (318), and a register array (628) for receiving and storing data from the crosspoint switch (318) according to the first and second control signals, for receiving and storing data from the host interface (606) according to the first and second control signals, and for communicating stored data to the crosspoint switch (318) according to the first and second control signals.

Abstract: An envelope detector operable to detect and record the minimum and maximum values present in a data stream. In various embodiments, the envelope detector includes a memory operable to store first and second data values, a first comparator, and a second comparator. The first comparator is generally operable to compare the first data value to a first input from the data stream and output a first control signal to cause the memory to store the first input as the first data value if the first input is greater than the first data value. The second comparator is generally operable to compare the second data value to the second input from the data stream and output a second control signal to cause the memory to store the first input as the second data value if the first input is less than the first data value.

Abstract: A method of processing a useable particulated nepheline syenite including providing particulate nepheline syenite with a maximum first grain size; milling the nepheline syenite in a ball mill operated substantially dry to produce a dry feed stock with particles less than a given size; and, using an air classifier to remove particles having a second grain size from the feed stock to provide an Einlehner Abrasive Value of less than about 100. In practice the second grain size is less than 5 microns and the distribution profile is generally 4-5 microns. The product produced by the method is, thus, novel.

Abstract: A method of controlling a valve of a cam phaser of an internal combustion engine includes determining a delta duty cycle from a position error and a rate of change of error (error dot). A fuzzy gain value is calculated from the delta duty cycle and a correction term. A duty cycle is calculated from an integral gain value and the fuzzy gain value. The duty cycle is then used to control the valve of the cam phaser.

Abstract: A method of processing a useable particulated nepheline syenite including providing particulate nepheline syenite with a maximum first grain size; milling the nepheline syenite in a ball mill operated substantially dry to produce a dry feed stock with particles less than a given size; and, using an air classifier to remove particles having a second grain size from the feed stock to provide an Einlehner Abrasive Value of less than about 100. In practice the second grain size is less than 5 microns and the distribution profile is generally 4-5 microns. The product produced by the method is, thus, novel.

Abstract: Nepheline syenite powder with a controlled particle size where 99.9% of the particles are less than 6 microns, which powder has a moisture content of less than 0.8% and an Einlehner Abrasive Value of less than 100 and products using this fine grain ultra fine nepheline syenite powder.

Abstract: A useable particulate nepheline syenite having a grain size to provide an Einlehner Abrasive Value of less than about 100 is described. The particulate nepheline syenite is generally free from agglomeration and moisture free. At least 99% of the nepheline syenite particles have a size less than 10 microns. In practice, the nepheline syenite grain size is less than about 5 microns and the distribution profile of the particulate system is generally 4-5 microns.

Abstract: A method and system estimates manufacturing costs for conventional and advanced materials and processes based on process-oriented approach. A computer system input display for selecting one or more designs and one or more design parameters. Cost models are based upon process-oriented manufacturing cost estimates for a plurality of designs utilizing materials and manufacturing processes. Software is programmed to receive selected designs and selected design parameters from the input display and pass the selected designs and design parameters to the cost models. An output display shows the manufacturing costs estimated by the cost models for the selected designs and design parameters. A manufacturing process flow simulation model highlights and quantifies the magnitude of the manufacturing process cost drivers. An architecture including a relational database is also disclosed, and input and editing modules can be utilized to modify the cost model equations or to provide input from other software applications.

Abstract: A paint manufacturing method includes receiving each of a group of fluid prepaints at different inputs of a fluid component mixing system, determining at a computer system a first fluid prepaint ratio, and mixing the fluid prepaints in accordance with the first ratio to form a base paint at an output of the mixing system. A paint manufacturing system includes a computer-controlled prepaint mixing system. The prepaint mixing system includes multiple fluid inputs providing for computer-controllable flow of prepaints into the mixing system. The computer system includes a memory storing software instructions that configured the computer system to receive user input selecting a base paint to be produced, determine a ratio of fluid prepaints needed to produce the base paint, and regulate each fluid flow control to establish, in the determined ratio, a flow of fluid prepaints entering the fluid mixing system.

Abstract: The present invention is an orally administered liquid pharmaceutical composition that demonstrates excellent physical stability while delivering concentrated levels of the pharmaceutical active(s). Specifically, these compositions for extended periods do not allow the active to precipitate or settle out of solution. Among the advantages of this invention is that the compositions do not require agitation/shaking prior to use as a method to re-suspend or dissolve active drug material to insure even and consistent dosing.