Patent application number | Description | Published |
20080297242 | INTEGRATED CIRCUIT HAVING A MULTI-PURPOSE NODE CONFIGURED TO RECEIVE A THRESHOLD VOLTAGE AND TO PROVIDE A FAULT SIGNAL - An integrated circuit includes a monitor node adapted to receive a monitored signal. The integrated circuit also includes a multi-purpose node. The integrated circuit is adapted to receive and store a threshold presented at the multi-purpose node during a first time period. The integrated circuit is also adapted to output a fault signal from the multi-purpose node at a time after the predetermined time period. The fault signal is indicative of a relationship between the monitored signal and the threshold. With this arrangement, the multi-purpose node achieves at least two functions. | 12-04-2008 |
20090174395 | METHODS AND APPARATUS FOR ANGULAR POSITION SENSING USING MULTIPLE QUADRATURE SIGNALS FROM FREQUENCY INDEPENDENT SINUSOIDS - A sensor minimizes effects of sensor element misalignment with respect to a magnet. In one embodiment, a sensor comprises a magnet, first, second, third, and fourth sensor elements positioned in relation to the magnet, and a signal processing module to process output signals from the first, second, third, and fourth sensor elements and generate first and second differential signals for minimizing effects of positional misalignment of the first, second, third, and fourth sensor elements with respect to the magnet by maximizing a quadrature relationship of the first and second differential signals. | 07-09-2009 |
20090212771 | HYSTERESIS OFFSET CANCELLATION FOR MAGNETIC SENSORS - Presented is a sensor that includes a magnetoresistive (MR) sensing device to sense a magnetic field and to produce an AC signal voltage proportional to the sensed magnetic field. The sensor also includes circuitry, coupled to the MR sensing device, to remove DC offset from the AC signal voltage. The DC offset may be related to the hysteresis characteristics of the MR sensing device. To remove DC offset, the circuitry may obtain an averaged DC offset and subtract the averaged DC offset from the AC signal voltage to produce a sensor output signal. | 08-27-2009 |
20100127655 | CLOSED-LOOP MOTOR DRIVER COMPENSATION - A control loop circuit for use in a closed-loop control system that controls a system such as a linear motor is presented. The control loop circuit includes a lead-lag compensator that features a lead compensation network configured to reduce output noise without substantially changing the effect of the lead compensation in the control system's frequency response. | 05-27-2010 |
20110055442 | LINEAR OR ROTATIONAL MOTOR DRIVER IDENTIFICATION - A mechanism for assigning unique addresses to identical devices attached to a serial bus is presented. Each device has at least one output and is provided with a storage device to provide a configurable portion of a bus address having a fixed portion and a configurable portion. The device is further provided with circuitry, coupled to the storage device and the output, to determine a state of the output and use the state to configure the configurable portion. Once the configurable portion is configured, the bus address uniquely identifies the device. Such configuration allows more than one such device to be coupled to the same serial bus, e.g., an I | 03-03-2011 |
20120086442 | Magnetic Field Sensor and Method Used in a Magnetic Field Sensor that Adjusts a Sensitivity and/or an Offset Over Temperature - A magnetic field sensor and a method associated with the magnetic field sensor provide gain correction coefficients and/or offset correction coefficients stored in the magnetic field sensor in digital form. The gain correction coefficients and/or offset correction coefficients can be used to generate analog control signals to control a sensitivity and/or an offset of an analog signal path through the magnetic field sensor. | 04-12-2012 |
20120146570 | CLOSED-LOOP MOTOR DRIVER COMPENSATION - A control loop circuit for use in a closed-loop control system that controls a system such as a linear motor is presented. The control loop circuit includes a lead-lag compensator that features a lead compensation network configured to reduce output noise without substantially changing the effect of the lead compensation in the control system's frequency response. | 06-14-2012 |
20120313636 | HYSTERESIS OFFSET CANCELLATION FOR MAGNETIC SENSORS - Presented is a sensor that includes a magnetoresistive (MR) sensing device to sense a magnetic field and to produce an AC signal voltage proportional to the sensed magnetic field. The sensor also includes circuitry, coupled to the MR sensing device, to remove DC offset from the AC signal voltage. The DC offset may be related to the hysteresis characteristics of the MR sensing device. To remove DC offset, the circuitry may obtain an averaged DC offset and subtract the averaged DC offset from the AC signal voltage to produce a sensor output signal. | 12-13-2012 |
20130093416 | Magnetic Field Sensor and Method Used in a Magnetic Field Sensor That Adjusts a Sensitivity and/or an Offset Over Temperature - A magnetic field sensor and a method associated with the magnetic field sensor provide gain correction coefficients and/or offset correction coefficients stored in the magnetic field sensor in digital form. The gain correction coefficients and/or offset correction coefficients can be used to generate analog control signals to control a sensitivity and/or an offset of an analog signal path through the magnetic field sensor. | 04-18-2013 |
Patent application number | Description | Published |
20090001708 | One piece self-expiring security badge or label - A self-expiring badge or label is provided that includes a clear substrate, an opaque adhesive layer, a liner web, and an ink pattern is provided. The clear substrate has a back surface and a front surface with the opaque adhesive layer on the back surface. The liner web has a first surface and a second surface, where the adhesive layer secures the substrate to the first surface. The ink pattern is on at least a portion of the second surface. Upon removal of the liner web from the adhesive layer, the portion remains secured to the clear substrate by the adhesive layer and the clear substrate is foldable to place the ink pattern in contact with the adhesive layer. The ink pattern migrates through the adhesive layer in a selected time interval and is visible through the clear substrate when the ink pattern is in contact with the adhesive layer. | 01-01-2009 |
20090052285 | One piece self-expiring security badge or label with devices to print, activate and issue the time-label automatically - A self-expiring badge or label that includes an upper substrate having an upper surface and a lower surface and an adhesive activator layer on the lower surface. A protective layer having a first surface and a second surface is provided, with the first surface of the protective layer being removably attached to and overlaying the adhesive layer. A lower substrate is provided that has an upper surface and a lower surface, the upper surface being removably attached to and overlaying the second surface of the protective layer. A migrating ink pattern is on the lower surface of the lower substrate. To activate, the upper substrate and at least a portion of the lower substrate are removed from the protective layer to leave a remaining portion of the lower substrate having the migrating ink pattern thereon. The migrating ink pattern is then contacted with the exposed adhesive activator layer to activate the migrating ink pattern to migrate through the adhesive activator layer and upper substrate in a selected time interval for viewing from the upper surface of the upper support layer to indicate an expired badge or label. Preferably the migrating ink pattern is contacted with the adhesive layer by folding it onto the adhesive layer. Optionally, to activate the badge both substrates are completely removed from the protective layer and the migrating ink pattern is contacted with the adhesive layer. | 02-26-2009 |
20110129394 | INSPECTION AND TESTING INDICATOR - An indicator is disclosed that detects the presence of a chemical residue. The indicator includes a substrate having an upper surface and a lower surface and a first portion and a second portion joined at a fold line. The first portion is smaller in area than the second portion. An adhesive coats the upper surface of at least the second portion of the substrate. A first reactant is adhered to the upper surface of the first portion of the substrate. When the second portion is contacted with a surface containing the chemical residue, the residue adheres to the adhesive and when the first portion is subsequently folded along the fold line so that the upper surfaces of the substrate contact each other, a portion of the adhesive on the second portion remains exposed and the first reactant and chemical residue react to provide the color indicia indicating the presence of the chemical residue. | 06-02-2011 |
20120042479 | Clip for fabrics - A unitary one piece badge holder for attachment to a garment, e.g., fabric pocket. The holder includes a substantially planar clip body having a front and rear surface and side edges. An opening in the clip body passes through the front and rear surfaces forming a periphery structure in the clip body. The structure has an interior wall surrounding the opening. A substantially planar flexible central spring member having front and rear surfaces and a surrounding edge surface appends from a top portion of the periphery structure. The opposing free end terminates within the opening near a bottom portion of the structure. The spring member and periphery structure are within the same plane. The gap between the surrounding edge surface of the spring member and the interior wall of the periphery structure decreases in width from the bottom portion of the peripheral structure to the top portion of the peripheral structure. Preferably a plurality of projecting elements project from the surrounding edge surfaces of the spring member and from the front surface of the central spring member to assist in firmly holding the fabric in the clip. A badge mounting member projects from the front surface of the top portion of the periphery structure upon which a badge can be mounted. When the spring member is flexed, preferably toward the rear surface of the clip body, out of the plane of the clip body, it creates a spring force. With the garment fabric placed over, preferably, the front surface of the spring member and pushed toward the top of the periphery structure, the spring force returns the spring member toward the plane of the clip body to grasp the fabric while the gap pinches the fabric to firmly secure it in the clip while displaying the badge. | 02-23-2012 |