Abstract: Systems, methods, and computer readable medium described herein relate to techniques for characterizing and/or anomaly detection in integrated circuits such as, but not limited to, field programmable gate arrays (FPGAs) and application-specific integrated circuits (ASICs). In one example aspect of certain example embodiments, a fully digital technique relies on the pulse width of signals propagated through a path under test. In another example aspect, the re-configurability of the integrated circuit is leveraged to combine the pulse propagation technique with a delay characterization technique to yield better detection of certain type of Trojans and the like. Another example aspect provides for running the test through reconfigurable path segments in order to isolate and identify anomalous circuit elements. Yet another example aspect provides for performing the characterization and anomaly detection without requiring golden references and the like.

Abstract: Disclosed are devices and methods for providing solar lighting and power to a consumer using pay-as-you-go technology. The pay-as-you-go technology allows for a user to pay for home power and lighting on an incremental basis as they use the device. The payments are made using a user's cell phone. A pay-as-you-go lighting apparatus may include a lighting module configured to provide lighting to a customer when activated, and a control system including a processor and a memory configured to monitor usage of the lighting apparatus, track remaining usage credits, and disable the lighting apparatus when there are no remaining usage credits.

Abstract: An example embodiment provides a transceiver for communication includes a timing determiner that detects a fall from high level to low level of a bus signal generated by pulse width modulation of a clock signal and input from a communication bus; a transmission data signal delay adjuster that determines a second timing having a predetermined time difference from a first timing, the bus signal rising from the low level to the high level at the first timing; an encoder that extends a low level of the bus signal by changing a data signal to be output to the communication bus from high level to low level; and a timing adjustment circuit that changes the data signal to the low level at the second timing.

Abstract: A remote controlled construction vehicle that can be battery powered and have movement members and a tool. The vehicle in one implementation can have wheels and a bucket and may include redundant safety and control systems that inhibit inadvertent startup of the vehicle or tool. The safety and control systems may also disable the vehicle in response to detecting faults.

Abstract: Systems and methods are provided for securing and authenticating a network of a vehicle. At least one network key is generated by an electronic control module and distributed to at least one remote device over a wired power line. At least one signed transmission having a signature based on the at least one network key is transmitted from the at least one remote device to the electronic control module over a communication channel on the network separate from the wired power line. The electronic control module authenticates and encrypts the at least one signed transmission and receives a data stream from the at least one remote device over the communication channel.

Abstract: A load control system may include multiple control devices that may send load control messages to load control devices for controlling an amount of power provided electrical loads. To prevent collision of the load control messages, the load control messages may be transmitted using different wireless communication channels. Each wireless communication channel may be assigned to a load control group that may include control devices and load control devices capable of communicating with one another on the assigned channel. A control device may send load control messages to a load control device within a transmission frame allocated for transmitting load control messages. The transmission frame may include equal sub-frames and load control messages may be sent at a random time within each sub-frame. Control devices may detect a status event within a sampling interval to offset transmissions from multiple control devices based on detection of the same event.

Abstract: Exemplary embodiments for use in a communications source network node for identifying a destination port associated with a destination network node to which a selected network link is connected. The embodiments include receiving a communications protocol packet at a destination network node via said selected network link connected to the destination port associated with the destination network node; inspecting the packet for a predetermined identifier; and if the predetermined identifier is present in said packet then outputting an indication that the identifier has been received comprising an identification of the destination port via which the packet was received. The indication is output by at least one of illumination for a pre-set period of a destination switch associated with the destination port, and by an output provided via a user interface of a network interface controller associated with the destination port.

Abstract: A method used in a remote control system for remotely controlling an appliance by execution of a remote control command contained in a control program stored in an operation terminal device, by which: a first identifier is acquired at a first time point (S801), the first identifier being unique to a portable medium located close to an operation terminal device serving as a remote controller for the appliance; the first identifier is embedded into the control program (S802); a second identifier is acquired at a second time point later than the first time point (S803), the second identifier being unique to a portable medium located close to the operation terminal device serving as the remote controller for the appliance; whether the first identifier matches the second identifier is determined (S804); and remote control of the appliance is prohibited when the first identifier does not match the second identifier (S805).

Abstract: Embodiments of the invention relate to the field of RFID (radio frequency identification). Some particularly preferred embodiments relate to a high-Q, so-called “full duplex” (FDX) RFID Reader. An RFID tag reader, the reader comprising: an electromagnetic (em) field generator for generating an electromagnetic (em) field for modulation by said tag, said modulation comprising modulated load of said em field by said tag; a detector system responsive to fluctuations in strength of said em field at said reader; a negative feedback system responsive to said detector system to provide a control signal for said em field generator for controlling said em field generator to reduce said detected fluctuations; and a demodulator responsive to said control of said em field to demodulate said em field modulation by said tag.

Abstract: In one embodiment, an apparatus includes a circuit coupled to a line, where the circuit may power a device, and where the power is transmitted to the device over the line as a pulse-width modulated signal. The circuit may set a duty cycle of the pulse-width modulated signal in order to transmit a determined power level to the device. The apparatus may vary a frequency of the pulse-width modulated signal to transmit data to the device while the duty cycle of the pulse-width modulated signal is fixed in order to continue to transmit the determined power level to the device. A variation in the frequency of the pulse-width modulated signal may be detectable by the device and represents at least a portion of the data.

Abstract: A process for transfer of signals is provided between a first control unit and at least a second control unit, wherein the first control unit, based on the input data, selects at least a first signal that is to be transferred, and the first control unit has at least one signal output, at which a first PWM signal can be emitted, wherein a first PWM signal is encoded and assigned to each selected at least one first signal, and wherein the second control device has one first signal input, which receives the first PWM signal and the second control device evaluates the first PWM signal received and detects the first signal and, based on the first signal transferred, creates a subsequent control instruction. A related device is also disclosed.

Abstract: A power line communication system transmits a dimming level to an electronic ballast to regulate the power consumed by a lamp. The power line controller has a notch generation circuit that generates notches on an AC power signal with a time duration in accordance with the dimming level of the lamp. A dimming interface associated with the electronic ballast detects the notches on the AC power signal. The dimming interface generates a ballast dimming level signal with a signal level related to the time duration of these notches.

Abstract: A transmission device includes a pulse modulated signal generator that generates a pulse-modulated signal by changing the width of a pulse or the density of a pulse according to the magnitude of the amplitude component of an input signal while discretely changing the pulse height according to the magnitude of the amplitude, a modulated-signal generator that generates a modulated signal by integrating the pulse-modulated signal and the phase component of the input signal, a power amplifier that includes at least as many amplifiers as the number of the discrete amplitude levels of the modulated signal, changes the number of amplifies that amplify the modulated signal on the basis of the value of the amplitude level of the modulated signal, combines outputs of the amplifiers, and outputs a combined output, and an output filter that eliminates a square-wave component from the output of the power amplifier.

Abstract: In one embodiment, an apparatus includes a circuit coupled to a line, where the circuit may power a device, and where the power is transmitted to the device over the line as a pulse-width modulated signal. The circuit may set a duty cycle of the pulse-width modulated signal in order to transmit a determined power level to the device. The apparatus may vary a frequency of the pulse-width modulated signal to transmit data to the device while the duty cycle of the pulse-width modulated signal is fixed in order to continue to transmit the determined power level to the device. A variation in the frequency of the pulse-width modulated signal may be detectable by the device and represents at least a portion of the data.

Abstract: A dynamoelectric machine assembly for connection to a system controller. The assembly includes at least one input contact for receiving a control signal from the system controller and a processor coupled to the input contact. The processor is configured to operate the assembly in a pulse width modulation (PWM) mode when the control signal is a PWM control signal and to operate the assembly in a serial mode when the control signal is a serial communication signal.

Abstract: A motor control method comprises: inputting a PWM signal into a control unit for the control unit to obtain a direction command and a speed command by an identification rule, and generating a control signal according to the direction and speed commands by the control unit; and generating a driving signal according to the control signal by the driving unit for driving a motor to operate according to the direction and speed commands.

Abstract: Systems and methods for the demodulation of pulse edge modulated signals for communications systems which are useful in body implanted electronics. A pulse edge modulated signal is generated by retarding or advancing each pulse edge of a carrier to be modulated relative to its original position in time, depending on the state of the digital bit to be modulated on that edge. Each modulated edge of a pulse edge modulated signal is demodulated by determining the position in time of the modulated edge relative to the original respective position of the modulated edge prior to modulation.

Abstract: A dynamoelectric machine assembly for connection to a system controller. The assembly includes at least one input contact for receiving a control signal from the system controller and a processor coupled to the input contact. The processor is configured to operate the assembly in a pulse width modulation (PWM) mode when the control signal is a PWM control signal and to operate the assembly in a serial mode when the control signal is a serial communication signal.