Abstract: Techniques and architecture are disclosed for array of light emitting diodes. For example, the array may comprise a plurality of stages, each stage comprising a plurality of light emitting diodes (LEDs) connected to a floating switch, respectively. The LEDs may be arranged substantially linearly on a circuit board in a plurality of clusters, where a distance between adjacent LEDs within a cluster is smaller than a distance between LEDs in adjacent clusters. Adjacent clusters contain LEDs from different stages and each stage contains LEDs in different clusters. The array may be incorporated in a lighting system. The light system may have a closed loop feedback mechanism which directly detects light emitted from a subset of the LEDs and a controller which controls the array based on the detection.

Abstract: A rechargeable battery system including at least one energy storage cell having a positive terminal and a negative terminal, a resistive element and a circuit configured to allow current to flow through the resistive element. A monitoring circuit measures the current flow through, and a voltage produced across, the resistive element and calculates the resistance of the resistive element. The current flow through the resistive element produces heat by raising the temperature of the resistive element. The current flow through the resistive element may be managed by a balancing circuit. A current sense resistor may be connected in series with a balancing resistor and a transistor turns on a balancing operation through balancing resistor. The monitoring circuit may determine the temperature of the resistive element based on the calculated resistance. The battery monitoring circuit may activate a battery cooling system based on the temperature of the resistive element.

Abstract: An AC lighting system where the intensity and/or color may be controlled by varying an output current level of a linear current regulator between a first current level and a second current level and/or varying ON times of a plurality of LED stages, respectively. When the current reaches the second current level, the output current level of the linear current regulator may be maintained at the second current level while ON times are varied is provided. Also provided is an AC lighting system where each switch may be selectively operated to provide power to a bootstrap conditioning network during the period of time when the applied voltage is insufficient to turn on the one or more LEDs corresponding to the respective switch when an LED ON time is short, such that power is provided to respective level shifted drive.

Abstract: Techniques and architecture are disclosed for array of light emitting diodes. For example, the array may comprise a plurality of stages, each stage comprising a plurality of light emitting diodes (LEDs) connected to a floating switch, respectively. The LEDs may be arranged substantially linearly on a circuit board in a plurality of clusters, where a distance between adjacent LEDs within a cluster is smaller than a distance between LEDs in adjacent clusters. Adjacent clusters contain LEDs from different stages and each stage contains LEDs in different clusters. The array may be incorporated in a lighting system. The light system may have a closed loop feedback mechanism which directly detects light emitted from a subset of the LEDs and a controller which controls the array based on the detection.

Abstract: System for braking either linear or rotary electric motor having no permanent magnets comprising at least one servo amplifier and an electronic circuit for generating a pulsed control signal for controlling the braking of the motor. The electronic circuit of the present invention may be responsive to any emergency such as loss of the line power, a motion controller failure, or actuation of a limit switch by a driven member. A method of braking is also disclosed.

Abstract: The invention provides a method and apparatus for maintaining the force, or torque, delivered by a variable reluctance motor as the speed of the motor increases. The method comprises the steps of sensing the speed of the motor and varying the number of turns of the motor's phase coil based on the sensed speed. The apparatus includes a motor speed sensor for sensing the speed of the motor and an inductance switch for switching the number of turns of the phase coil from a first value to a second value based on the sensed speed. One embodiment of the invention includes an inductance compensation circuit to compensate for the change in load inductance when the number of turns of the phase coil is switched.

Abstract: The invention provides a method and apparatus for maintaining the force, or torque, delivered by a variable reluctance motor as the speed of the motor increases. The method comprises the steps of sensing the speed of the motor and varying the number of turns of the motor's phase coil based on the sensed speed. The apparatus includes a motor speed sensor for sensing the speed of the motor and an inductance switch for switching the number of turns of the phase coil from a first value to a second value based on the sensed speed. One embodiment of the invention includes an inductance compensation circuit to compensate for the change in load inductance when the number of turns of the phase coil is switched.