Patent application number | Description | Published |
20090222231 | Method and device for correcting a signal of a sensor - A method and a device for correcting a signal of a sensor provide for maximally accurate drift compensation of a characteristics curve of the sensor. At least one characteristic quantity of the signal of the sensor is compared with a reference value. The signal of the sensor is corrected as a function of the comparison result. A value of the at least one characteristic quantity of the signal of the sensor derived from the signal of the sensor is formed as the reference value. | 09-03-2009 |
20090236610 | Method for Manufacturing a Semiconductor Structure, and a Corresponding Semiconductor Structure - A method for manufacturing a semiconductor structure is provided which includes the following operations: supplying a crystalline semiconductor substrate, providing a porous region adjacent to a surface of the semiconductor substrate, introducing a dopant into the porous region from the surface, and thermally recrystallizing the porous region into a crystalline doping region of the semiconductor substrate whose doping type and/or doping concentration and/or doping distribution are/is different from those or that of the semiconductor substrate. A corresponding semiconductor structure is likewise provided. | 09-24-2009 |
20100035068 | Method for producing a silicon substrate having modified surface properties and a silicon substrate of said type - A method for producing a silicon substrate, including the steps of providing a silicon substrate having an essentially planar silicon surface, producing a porous silicon surface having a plurality of pores, in particular having macropores and/or mesopores and/or nanopores, applying a filling material that is to be inserted into the silicon, which has a diameter that is less than a diameter of the pores, inserting the filling material into the pores and removing the excess filling material form the silicon surface, if necessary, and tempering the silicon substrate that is furnished with the filling material that has been filled into the pores, at a temperature between ca. 1000° C. and ca. 1400° C., in order to close the generated pores again and to enclose the filling material. | 02-11-2010 |
20100283147 | METHOD FOR PRODUCING A PLURALITY OF CHIPS AND A CHIP PRODUCED ACCORDINGLY - A production method for chips, in which as many method steps as possible are carried out in the wafer composite, that is, in parallel for a plurality of chips disposed on a wafer. This is a method for producing a plurality of chips whose functionality is implemented on the basis of the surface layer of a substrate. In this method, the surface layer is patterned and at least one cavity is produced below the surface layer, so that the individual chip regions are connected to each other and/or to the rest of the substrate by suspension webs only, and/or so that the individual chip regions are connected to the substrate layer below the cavity via supporting elements in the region of the cavity. The suspension webs and/or supporting elements are cut when the chips are separated. The patterned and undercut surface layer of the substrate is embedded in a plastic mass before the chips are separated. | 11-11-2010 |
20110019337 | METHOD OF MANUFACTURING A PLANAR ELECTRODE WITH LARGE SURFACE AREA - A method for fabricating a pair of large surface area planar electrodes. The method includes forming a first template above a first substrate, the first template having a first plurality of pores, coating the first plurality of pores of the first template with a first layer of conducting material to form a first electrode, placing the first plurality of pores of the first electrode in proximity to a second electrode, thereby forming a gap between the first plurality of pores and the second electrode, and filling the gap with an electrolyte material. | 01-27-2011 |
20120132925 | METHOD FOR MANUFACTURING A SEMICONDUCTOR STRUCTURE, AND A CORRESPONDING SEMICONDUCTOR STRUCTURE - A method for manufacturing a semiconductor structure is provided which includes the following steps: a crystalline semiconductor substrate ( | 05-31-2012 |
Patent application number | Description | Published |
20090206422 | Micromechanical diaphragm sensor having a double diaphragm - A method for producing a micromechanical diaphragm sensor, and a micromechanical diaphragm sensor produced with the method. The micromechanical diaphragm sensor has at least one first diaphragm as well as a second diaphragm, which is disposed essentially on top of the first diaphragm. Furthermore, the micromechanical diaphragm sensor has a first cavity and a second cavity, which is essentially disposed above the first cavity. | 08-20-2009 |
20110151620 | METHOD FOR MANUFACTURING CHIPS - A method for manufacturing chips ( | 06-23-2011 |
20110169107 | Method for manufacturing a component, method for manufacturing a component system, component, and component system - A process for manufacturing a component is described. In a first manufacturing step a base structure having a substrate, a diaphragm, and a cavern region is provided. The diaphragm is oriented substantially parallel to a main plane of extension of the substrate. The cavern region is situated between the substrate and the diaphragm, and has an access opening. In a second manufacturing step, a first conductive layer is provided at least partially in the cavern region, in particular on a second side of the diaphragm facing the substrate, perpendicularly to the main plane of extension. | 07-14-2011 |
20130234270 | Atomic Layer Deposition Strengthening Members and Method of Manufacture - In one embodiment, a method of forming a semiconductor device includes providing a substrate, forming a sacrificial layer above the substrate layer, forming a first trench in the sacrificial layer, forming a first sidewall layer with a thickness of less than about 50 nm on a first sidewall of the first trench using atomic layer deposition (ALD), and removing the sacrificial layer. | 09-12-2013 |
Patent application number | Description | Published |
20100079119 | SYSTEM AND METHOD FOR LIMITING CURRENT OSCILLATION - A system and method for limiting current oscillation in power supplies. A method for operating a power supply comprises entering a current limitation mode, setting a current limit for a current flowing through a power switch of the power supply, and in response to determining a current limit has changed from a high value to a low value or detecting an occurrence of a fault condition, setting the current limit to the low value, and locking the current limit so that the current limit does not change. The method further comprises providing a current to a load coupled to the power supply. | 04-01-2010 |
20100079193 | SEMICONDUCTOR SWITCH AND METHOD FOR OPERATING A SEMICONDUCTOR SWITCH - A semiconductor switch, is provided that comprises a semiconductor element having a control terminal and two load terminals forming switching contacts of the semiconductor switch, a temperature measuring device for measuring the temperatures of the semiconductor element at two measurement locations spaced apart from one another, and also a control circuit connected between the temperature measuring device and the control terminal of the semiconductor element and having a control input forming the control contact of the semiconductor element, wherein provision is made for: measuring the temperatures of the semiconductor element at two measurement locations spaced apart from one another; providing a signal representing the difference between the two temperatures; driving a driving current of specific intensity into the control terminal of the semiconductor element if a corresponding signal is present at the control input in order to control the semiconductor element in the conducting state between its load terminals; increasing the intensity of the driving current if the semiconductor element is controlled in the conducting state and the temperature difference exceeds a first limit value. | 04-01-2010 |
20100079197 | Method for Operating a Power Semiconductor Circuit and Power Semiconductor Circuit - In a method for operating a power semiconductor circuit a power semiconductor chip is provided which includes a power semiconductor switch with a first load terminal and with a second load terminal. Further, a first temperature sensor which is thermally coupled to the power semiconductor switch and a second temperature sensor are provided. The power semiconductor switch is switched OFF or kept switched OFF if the temperature difference between a first temperature of the first temperature sensor and a second temperature of the second temperature sensor is greater than or equal to a switching-OFF threshold temperature difference which depends, following an inconstant first function, on the voltage drop across the power semiconductor switch between the first load terminal and the second load terminal. | 04-01-2010 |
20110109372 | Semiconductor Device with Thermal Fault Detection - A semiconductor device with a thermal fault detection is disclosed. According to one example of the invention such a semiconductor device includes a semiconductor chip including an active area. It further includes a temperature sensor arrangement that provides a measurement signal dependent on the temperature in or close to the active area, the measurement signal having a slope of a time-dependent steepness, and an evaluation circuit that is configured to provide an output signal that is representative of the steepness of the slope of the measurement signal and further configured to signal a steepness higher than a predefined threshold. | 05-12-2011 |
20110157756 | Semiconductor Device with Overcurrent Protection - A semiconductor device with an over-current detection feature is disclosed. According to an example of the invention the device includes: a semiconductor chip including a load current path that conducts a load current in response to an input signal activating the load current flow. A current sensor arrangement provides a measurement signal representing the load current. An evaluation circuit is configured to compare the measurement signal with a first threshold and to signal an over-current when the measurement signal exceeds the first threshold after a delay time period starting from the activation of the load current flow has elapsed. | 06-30-2011 |
20110316606 | Power Switch Temperature Control Device and Method - An embodiment method for power switch temperature control comprises monitoring a power transistor for a delta-temperature fault, and monitoring the power transistor for an over-temperature fault. If a delta-temperature fault is detected, then the power transistor is commanded to turn off. If an over-temperature fault is detected, then the power transistor is commanded to turn off, and delta-temperature hysteresis cycling is disabled. | 12-29-2011 |
20120229193 | System and Method for Temperature Based Control of a Power Semiconductor Circuit - In a method for operating a power semiconductor circuit a power semiconductor chip is provided which includes a power semiconductor switch with a first load terminal and with a second load terminal. Further, a first temperature sensor which is thermally coupled to the power semiconductor switch and a second temperature sensor are provided. The power semiconductor switch is switched OFF or kept switched OFF if the temperature difference between a first temperature of the first temperature sensor and a second temperature of the second temperature sensor is greater than or equal to a switching-OFF threshold temperature difference which depends, following an inconstant first function, on the voltage drop across the power semiconductor switch between the first load terminal and the second load terminal. | 09-13-2012 |
20130027830 | Circuit with a Temperature Protected Electronic Switch - A method can be used for driving an electronic switch integrated in a semiconductor body. A first temperature is measured at a first position of the semiconductor body. A temperature propagation is detected in the semiconductor body. The electronic switch is switched off when the temperature at the first position rises above a first threshold that is set dependent on the detected temperature propagation. | 01-31-2013 |
20130147047 | Integrated Circuit and Method of Forming an Integrated Circuit - An integrated circuit includes a base element and a copper element over the base element, the copper element having a thickness of at least 5 μm and a ratio of average grain size to thickness of less than 0.7. | 06-13-2013 |
20130257515 | Method for Controlling a Semiconductor Component - A transistor monolithically integrated in a semiconductor body includes a first sub-transistor and a second sub-transistor that both include a first and second load contacts and a control contact for controlling an electric current through a load path. The first load contact of the first sub-transistor is electrically connected to the first load contact of the second sub-transistor and the second load contact of the first sub-transistor is electrically connected to the second load contact of the second sub-transistor. A control circuit is configured to cause the first sub-transistor to switch from a first state to a second state at a first point of time and to cause the second sub-transistor to switch from the first state to the second state at a second point of time subsequent to the first point of time. | 10-03-2013 |
20140085073 | DIRECTION INDICATOR CIRCUIT FOR CONTROLLING A DIRECTION INDICATOR IN A VEHICLE - A direction indicator circuit for controlling a direction indicator in a vehicle is provided. The direction indicator circuit may include a first terminal for connecting to a supply voltage terminal; a second terminal for connecting to a lighting means of a direction indicator and to a direction indicator switch; and a third terminal for connecting to a capacitor; wherein the direction indicator circuit is configured to provide the direction indicator with a current during an on state and with no current during an off state, wherein the duration of the on state and the duration of the off state are determined by the size of the capacitor; wherein the capacitor is discharged essentially constantly during the on state, and wherein the capacitor is charged essentially constantly during the off state. | 03-27-2014 |
20140085074 | DIRECTION INDICATOR CIRCUIT FOR CONTROLLING A DIRECTION INDICATOR IN A VEHICLE - A direction indicator circuit for controlling a direction indicator may include: a first terminal for connecting to a supply voltage terminal; a second terminal for connecting to a direction indicator switch and a lighting means; a third terminal for connecting to a capacitor; wherein the direction indicator circuit is designed to provide the lighting means with a current during an on state and with no current during an off state, wherein the duration of the on state and the duration of the off state are determined by a voltage at the capacitor; wherein the direction indicator circuit has a first and a second circuit, wherein the capacitor provides the supply voltage for the first and second circuits during the on state; wherein the current which flows through the first circuit has a negative temperature coefficient, and the current which flows through the second circuit has a positive temperature coefficient. | 03-27-2014 |
20140085075 | DIRECTION INDICATOR CIRCUIT FOR CONTROLLING A DIRECTION INDICATOR IN A VEHICLE - In various embodiments, a direction indicator circuit for controlling a direction indicator in a vehicle is provided. The direction indicator circuit may include: a first terminal for connecting to a supply voltage; a second terminal for connecting to a direction indicator switch and a lighting means; a third terminal for connecting to a capacitor; and a switch for providing a current, wherein the switch is connected to the first terminal and to the second terminal; wherein the direction indicator circuit is designed to provide the lighting means with a current during an on state using the switch and with no current during an off state; wherein during the on state the direction indicator circuit checks the provided current at least once and goes into the off state if the check detects a current which is lower than a predefined current. | 03-27-2014 |
20140332877 | Semiconductor Device - A switching component includes a control element and an integrated circuit. The integrated circuit includes a first transistor element and a second transistor element electrically connected in parallel to the first transistor element. The first transistor element includes first transistors, gate electrodes of which are disposed in first trenches in a first main surface of a semiconductor substrate. The second transistor element includes second transistors, gate electrodes of which are disposed in second trenches in the first main surface, and a second gate conductive line in contact with the gate electrodes in the second trenches. The control element is configured to control a potential applied to the second gate conductive line. | 11-13-2014 |
20140332881 | SEMICONDUCTOR DEVICE - A semiconductor device includes a transistor array, including first transistors and second transistors. Gate electrodes of the first transistors are disposed in first trenches in a first main surface of a semiconductor substrate, and gate electrodes of the second transistors are disposed in second trenches in the first main surface. The first and second trenches are disposed in parallel to each other. The semiconductor device further includes a first gate conductive line in contact with the gate electrodes in the first trenches, a second gate conductive line in contact with the gate electrodes in the second trenches, and a control element configured to control the potential applied to the second gate conductive line. | 11-13-2014 |
20150207306 | DISTINGUISHING BETWEEN OVERLOAD AND OPEN LOAD IN OFF CONDITIONS - Techniques are described for determining whether a switch circuit experienced one of a latched overload condition and an open load with no input voltage condition. In the techniques, a first diagnostic signal is output if the switch circuit experienced the latched overload condition. Also, in the techniques, a second, different diagnostic signal is output if the switch circuit experienced the open load with no input voltage condition. | 07-23-2015 |
20150277456 | TEMPERATURE DEPENDENT CURRENT LIMITING - In one example, a method includes determining, by a temperature sensor, a temperature of a device that controls an amount of current flowing to a load, and determining, based on the temperature of the device, a threshold current. The method also includes, in response to determining that the amount of current flowing to the load is greater than the threshold current, adjusting the amount of current flowing to the load. | 10-01-2015 |
20150280416 | CONTROLLED SWITCH-OFF OF A POWER SWITCH - A power circuit is described that includes a switch coupled to a resistive-inductive-capacitive load and a driver coupled to the switch. The driver is configured to detect an emergency event within the power circuit. After detecting the emergency event within the power circuit, the driver is further configured to perform a controlled emergency switch-off operation of the switch to minimize the maximum temperature of the switch during the detected emergency event and switch-off operation. | 10-01-2015 |