Patent application number | Description | Published |
20130207734 | ELECTRONIC CIRCUITRY - Electronic circuitry comprising operational circuits of active switching type requiring timing signals, and conductive means for distributing said timing signals to the operational circuits, wherein the timing signal distribution means includes a signal path that has different phases of a drive signal are supplied via active means at different positions about the signal path where that path exhibits endless electro-magnetic continuity without signal phase inversion or has interconnections with another signal path having different substantially unidirectional signal flow where there is no endless electromagnetic continuity between those signal paths and generally has non-linear associated circuit means where the signal path is of a transmission line nature. | 08-15-2013 |
20130221405 | APPARATUS AND METHOD FOR ELECTRONIC CIRCUIT PROTECTION - Apparatus and methods for electronic circuit protection are disclosed. In one embodiment, an apparatus comprises a well having an emitter and a collector region. The well has a doping of a first type, and the emitter and collector regions have a doping of a second type. The emitter region, well, and collector region are configured to operate as an emitter, base, and collector for a first transistor, respectively. The collector region is spaced away from the emitter region to define a spacing. A first spacer and a second spacer are positioned adjacent the well between the emitter and the collector. A conductive plate is positioned adjacent the well and between the first spacer and the second spacer, and a doping adjacent the first spacer, the second spacer, and the plate consists essentially of the first type. | 08-29-2013 |
20130222961 | APPARATUS AND METHOD FOR ELECTRONIC CIRCUIT PROTECTION - Apparatuses and methods for providing transient electrical event protection are disclosed. In one embodiment, an apparatus comprises a detection and timing circuit, a current amplification circuit, and a clamping circuit. The detection and timing circuit is configured to detect a presence or absence of a transient electrical event at a first node, and to generate a first current for a first duration upon detection of the transient electrical event. The current amplification circuit is configured to receive the first current from the detection and timing circuit and to amplify the first current to generate a second current. The clamping circuit is electrically connected between the first node and a second node and receives the second current for activation. The clamping circuit is configured to activate a low impedance path between the first and second nodes in response to the second current, and to otherwise deactivate the low impedance path. | 08-29-2013 |
20140025999 | TWO-WIRE COMMUNICATION SYSTEM FOR HIGH-SPEED DATA AND POWER DISTRIBUTION - Various embodiments of the present invention provide a two-wire (e.g., unshielded twisted pair) bus system that is simple (e.g., no microcontroller required in slave devices), synchronous with embedded clock information, inexpensive, automotive EMC compliant, and has sufficient speed and bandwidth for a large number of slave devices/peripherals, and also provides various protocols that can be used in various communication systems such as a two-wire bus system. The two-wire bus optionally may be self-powered, i.e., the master device may provide power to the slave devices over the two-wire bus. | 01-23-2014 |
20140055044 | LED CURRENT CONTROL SYSTEM FOR LED DRIVE SYSTEM WITH MULTIPLE DIMMING INPUTS - A LED current control system for use with an LED drive system which includes LED strings connected in series with respective current sink circuits, each of which causes a current to be conducted by the LED string to which it is connected. The drive system includes 3 or more ‘dimming’ inputs with which the LED string currents can be adjusted. The LED current control system comprises at least one minimum circuit which receives two or more dimming inputs and produces an output which is proportional to the lesser of the inputs, a multiplier circuit which receives the outputs of the minimum circuits and at least one other dimming input and produces an output ILED which is proportional to the product of the received signals, and a sink control circuit which receives ILED and controls the current sink circuits such that the string currents vary with ILED. | 02-27-2014 |
20140060186 | Detection and Mitigation of Aerodynamic Error Sources for Micromachined Inertial Sensors - Error sources related to aerodynamics of an inertial sensor resonator are detected by modulating the distance between the resonator and the underlying substrate and sensing modulated error signals in the accelerometer that are induced by such modulation. Compensating signals may be provided to substantially cancel errors caused by such error sources. | 03-06-2014 |
20140070382 | Pre-Molded MEMS Device Package - A MEMS lead frame package body encloses a MEMS device enclosed in an internal cavity formed by the mold body and cover. To accommodate a MEMS microphone, an acoustic aperture extends through the mold body. In some embodiments, a conductive column extends through the pre-molded body to allow electrical connection from a partially encapsulated lead frame to the conductive cover. Some embodiments may include a multi-tiered cavity within the mold body for mounting an integrated circuit separated by a gap above the MEMS device. | 03-13-2014 |
20140220723 | Methods and Structures for Using Diamond in the Production of MEMS - A MEMS device with movable MEMS structure and electrodes is produced by fabricating electrodes and shielding the electrodes with diamond buttons during subsequent fabrication steps, such as the etching of sacrificial oxide using vapor HF. In some embodiments, the diamond buttons are removed after the movable MEMS structure is released. | 08-07-2014 |
20140260515 | System and Method for Run-Time Hermeticity Detection of a Capped MEMS Device - Determining if a hermetically sealed MEMs device loses hermeticity during operation. In one embodiment, the MEMs device is an accelerometer. A test signal having an associated frequency above an operational frequency range for the accelerometer is provided to the accelerometer at an input during operation of the accelerometer for sensing an acceleration. The output signal of the accelerometer is filtered at least above the operational frequency range of the accelerometer producing a test output signal. The test output signal is then compared to a predetermined threshold to determine if the amplitude of the test output signal differs from the threshold. If the amplitude of the test output signal differs from the predetermined threshold, an error signal is produced indicating that hermeticity of the accelerometer has been lost. | 09-18-2014 |