Abstract: A microprocessor-PLD hybrid architecture includes an IPC microprocessor and a PLD in signal communication with the IPC microprocessor via an IPC interface. The IPC microprocessor outputs a data read command to initiate a data read operation or a data write command. The PLD includes a plurality of PLD modules that store data and a bus controller. The bus controller communicates with the plurality of PLD modules via a plurality of PLD interfaces and is configured to sequentially execute a set of bus controller instructions. The bus controller reads data from a target PLD module from among the plurality of PLD modules in response to receiving the data read command, and transfers the data to the IPC microprocessor. The bus controller receives data from the IPC microprocessor and stores the data in a target PLD module from among the plurality of PLD modules in response to receiving the data write command.

Abstract: A bus controller-based page memory programmable logic device (PLD) architecture includes a plurality of PLD modules and a bus controller in signal communication with the plurality of PLD modules via a universal bus interface. Each PLD module include a PLD memory unit configured to store first data. The bus controller includes bus memory unit configured to store second data and includes a bus controller engine configured to sequentially execute a set of bus controller instructions. One or both of the first data and the second data is transferred between the bus controller and a target PLD module among the plurality of PLD modules in response to sequentially executing the set of bus controller instructions.

Abstract: This application relates to a method of amplifying an radio frequency signal using a power amplifier, the method comprising the steps of: inputting a supply voltage into the power amplifier; inputting the radio frequency signal to be amplified into the power amplifier; inputting a time-calibrated bias signal into the power amplifier that varies based on an envelope signal produced from the radio frequency signal, said envelope signal indicating an envelope of the radio frequency signal and said bias signal being time calibrated to within 3 ns of the envelope of the radio frequency signal; and amplifying, by the power amplifier, the radio frequency signal based at least in part on the bias signal.

Abstract: A bus controller-based programmable logic device (PLD) architecture is provided and includes a dual-port unit interposed between bus controllers. The dual port unit includes first and second data transfer layers. The first data transfer layer includes write and read areas for data transfer between the first and second bus controllers, respectively. A write to the read area is prevented during a read by the second bus controller. The second data transfer layer includes read and write areas for data transfer between the first and second bus controllers, respectively. A write to the read area is prevented during a read by the first bus controller.

Abstract: A hoist application system is provided. The hoist application system includes a motor drive unit, which is receptive of a final duty command and which drives a motor in accordance with the final duty command, a closed-loop control unit configured to generate a closed-loop duty command, an open-loop control unit configured to generate an open-loop duty command and a switch logic unit. The switch logic unit is receptive of direct current (DC) system information, the closed-loop duty command and the open-loop duty command, and is configured to generate the final duty command from one of the closed-loop duty command and the open-loop duty command based on the DC system information.

Abstract: A motor temperature control system for an electric aircraft is provided. The motor temperature control system includes an electric motor, circuitry and a thermoelectric generator (TEG). The TEG is disposed in thermal communication with the electric motor. The TEG is electrically coupled to the circuitry such that heat generated by the electric motor is converted by the TEG to electrical energy that generates a voltage drop across the circuitry.

Abstract: A digital signal processing system to determine a position of a resolver includes a digital signal processor that includes first timer and second timer. The first timer creates a resolver excitation signal from a series of samples and creates an incrementing Crossing signal each time the resolver excitation signal crosses zero. When the Crossing signal has a first value, a multiplexer provides resolver sine signals to an analog to digital converter to convert the resolver sine signal to a series of digital sine samples, and the second timer stores the series of digital sine samples in a sine sample buffer. When the Crossing signal has a second value, the multiplexer provides the resolver cosine signal to the analog to digital converter to convert the resolver cosine signal to a series of digital cosine samples, and the second timer stores the series of digital cosine samples in a buffer.

Abstract: A lighting control system (1) comprising at least one lighting module (2) and a controller (3), the controller (3) being configured to cause the at least one lighting module to create a lighting scene for a lighting calendar event, the controller (3) further being configured to obtain first data by data mining social media content relating to the lighting calendar event, determine first lighting attributes from the first data, based on the first lighting attributes, control the at least one lighting module to generate at least one lighting scene and apply the at least one lighting scene for the lighting calendar event, obtain second data by data mining social media content relating to the applied at least one lighting scene, determine second lighting attributes from the second data, and based on the second lighting attributes control the at least one lighting module to generate at least one updated lighting scene and apply the at least one updated lighting scene for the lighting calendar event.

Abstract: An ejection system may comprise an ejection seat and a smart deployment system configured to initiate a deployment of the ejection seat. The smart deployment system may comprise a pilot health monitoring system including a plurality of sensors configured to detect a plurality of physiological conditions, and a controller configured to make ejection system decisions based on a pilot health signal received from the pilot health monitoring system and an aircraft health signal output from an aircraft health monitoring system.

Abstract: The invention relates to a monitoring system (13) for monitoring electrical devices (A, B, C, D, K) like luminaires. An assignments providing unit (7) provides assignments between the electrical devices and behavior classes defining expected behaviors, wherein a deviation determination unit (9) determines a deviation a) between a monitored behavior of an electrical device assigned to a behavior class and an expected behavior defined by a behavior class and/or b) between a monitored behavior of an electrical device and a monitored behavior of another electrical device, wherein an output unit (10) provides an output depending on the determined deviation. The deviation can be indicative of a commissioning error, i.e., for instance, of an assignment of an electrical device to a wrong room within a building. The monitoring system can therefore allow for an automatic detection of commissioning errors in a building which may have thousands of electrical devices.

Abstract: A lighting control system (1) comprising at least one lighting module (2) and a controller (3), the controller (3) being configured to cause the at least one lighting module to create a lighting scene for a lighting calendar event, the controller (3) further being configured to obtain first data by data mining social media content relating to the lighting calendar event, determine first lighting attributes from the first data, based on the first lighting attributes, control the at least one lighting module to generate at least one lighting scene and apply the at least one lighting scene for the lighting calendar event, obtain second data by data mining social media content relating to the applied at least one lighting scene, determine second lighting attributes from the second data, and based on the second lighting attributes control the at least one lighting module to generate at least one updated lighting scene and apply the at least one updated lighting scene for the lighting calendar event.

Abstract: Apparatus and methods for power detection in radio frequency (RF) systems are disclosed. In certain embodiments, a power detection system includes a power amplifier, a directional coupler connected to an output of the power amplifier, and a power detector that generates a differential power detection signal based on a single-ended radio frequency input signal received from the directional coupler. The differential power detection signal indicates an output power of the power amplifier, for example, a root mean square (RMS) output power.

Abstract: System and methods for motor drive electronics are provided. Aspects include receiving, by a controller on a motor driver electronics (MDE) component, voltage data associated with a thermoelectric generator, wherein the MDE component is configured to operate an electric motor, and wherein the MDE component comprises a power card including one or more components, determining a temperature reading based on the voltage data, enacting an action associated with the MDE component based at least in part on the temperature reading.

Abstract: An intelligent architecture system is provided. The intelligent architecture system includes an input line, an output line and an intelligent architecture operably interposed between the input line and the output line. The intelligent architecture is configured to control a voltage of the output line in accordance with a voltage of the input line.

Abstract: Examples described herein provide a method that includes storing, in a first buffer associated with a first ADC of a DSP, resolver sine values collected from first, second, and third resolvers. The method further includes storing, in a second buffer associated with a second ADC of the DSP, resolver cosine values collected from the first, second, and third resolvers. The method further includes storing, in a third buffer associated with a third ADC of the DSP, resolver excitation values collected from the first, second, and third resolvers. The method further includes determining a midpoint value of the resolver excitation values, determining a sine amplitude based at least in part on the resolver sine values and the midpoint value, and determining a cosine amplitude based at least in part on the resolver sine values and the midpoint value. The method further includes identifying a quadrant of a resolver position.

Abstract: A motor speed monitoring system can include a monitor channel having an input configured to connect to an inverter output of an inverter to receive motor command signals from the inverter, and an intelligence module configured to determine a motor speed based on the motor power signals from the inverter.

Abstract: Provided are embodiments for a method for variable differential transformer demodulation using a hybrid algorithm. The method can obtain a first feedback signal over a first half of a first cycle and a second feedback signal over a first half of a second cycle, and obtain a first calibration signal and a second calibration signal during a second half cycle of the first cycle. The method can also obtain an excitation signal over a second half of the second cycle, and determine a sensor position of the variable differential transformer based on the first feedback signal, the second feedback signal, and the excitation signal. Also provided are embodiments for a system for variable differential transformer demodulation using a hybrid algorithm.

Abstract: A system for controlling landing gear subsystems may comprise a controller and a first motor drive unit in operable communication with the controller. A first electric motor and a second electric motor may be in operable communication with the first motor drive unit. A second motor drive unit may be in operable communication with the controller. A third electric motor and a fourth electric motor may be in operable communication with the second motor drive unit. An AC/DC converter may be electrically coupled to the first drive unit and the second motor drive unit.

Abstract: A system for controlling a motor with a plurality of motor control functions including at least a current control loop and a velocity control loop. The system includes one of a hybrid Digital Signal Processor (DSP)-Field Programmable Gate Array (FPGA) architecture having an integral DSP and an integral FPGA or a System on a Chip (SoC) architecture having a Microcontroller Sub-System (MSS) and an FPGA fabric. The current control loop function is assigned to the integral FPGA for the hybrid DSP-FPGA architecture, and at least the velocity control loop function is assigned to the DSP the hybrid DSP-FPGA architecture. Alternatively, the current control loop function is assigned the FPGA fabric of the SoC architecture, and at least the velocity control loop function is assigned to the MSS of the SoC architecture.

Abstract: The invention relates to an operational state determination apparatus (1) for determining whether a variation in a determined electrical parameter of an electrical network (2) is caused by a variation in an operational state of an electrical consumer of the electrical network. The electrical network comprises multiple electrical consumers (3, 4, 5) and a voltage source (6), wherein a variation classification unit (10) determines whether a variation in the determined electrical parameter of the electrical network is caused by a variation in the operational state of an electrical consumer of the network depending on a decision variable which depends on a variation in a measured voltage and a variation in a measured current of the electrical network. This determination can be performed, without directly using the variation in the determined electrical parameter of the electrical network and is therefore less influenced by random voltage fluctuations in the electrical network.