子分类:
| 序号 | 专利名 | 申请号 | 申请日 | 公开(公告)号 | 公开(公告)日 | 发明人 |
|---|---|---|---|---|---|---|
| 201 | Systems using multi-layer-multi-turn high efficiency inductors | US13797629 | 2013-03-12 | US08823482B2 | 2014-09-02 | Vinit Singh; Jacob Babcock; Christine A. Frysz |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 202 | VARIABLE CORE ELECTROMAGNETIC DEVICE | US14228799 | 2014-03-28 | US20140210585A1 | 2014-07-31 | James Leo Peck, JR. |
| An electromagnetic device includes a variable magnetic flux core having a plurality of core sections stacked on one another. At least one core section of the plurality of core sections may include a different selected geometry and/or a different chosen material. The at least one core section is configured to provide a predetermined inductance performance. An opening is provided through the stacked plurality of core sections for receiving a conductor winding. An electrical current flowing through the conductor winding generates a magnetic field about the conductor winding and a magnetic flux flow in each of the plurality of core sections. The magnetic flux flow in the at least one core section is different from the other core sections in response to the different selected geometry and/or the different chosen material of the at least one core section to provide the predetermined inductance performance. | ||||||
| 203 | VERTICALLY INTEGRATED SYSTEMS | US14189805 | 2014-02-25 | US20140175600A1 | 2014-06-26 | Alan J. O'DONNELL; Santiago IRIARTE; Mark J. MURPHY; Colin G. LYDEN; Gary CASEY; Eoin Edward ENGLISH |
| Embodiments of the present invention provide an integrated circuit system including a first active layer fabricated on a front side of a semiconductor die and a second pre-fabricated layer on a back side of the semiconductor die and having electrical components embodied therein, wherein the electrical components include at least one discrete passive component. The integrated circuit system also includes at least one electrical path coupling the first active layer and the second pre-fabricated layer. | ||||||
| 204 | Method for operation of multi-layer-multi-turn high efficiency inductors | US13797534 | 2013-03-12 | US08710948B2 | 2014-04-29 | Vinit Singh; Jacob Babcock; Christine A. Frysz |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 205 | Method of manufacture of multi-layer-multi-turn high efficiency tunable inductors | US13797503 | 2013-03-12 | US08707546B2 | 2014-04-29 | Vinit Singh; Jacob Babcock; Christine A. Frysz |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 206 | Method for operation of multi-layer-multi-turn high efficiency tunable inductors | US13797581 | 2013-03-12 | US08698591B2 | 2014-04-15 | Vinit Singh; Jacob Babcock; Christine A. Frysz |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 207 | Multi-layer-multi-turn structure for high efficiency inductors | US13797387 | 2013-03-12 | US08680960B2 | 2014-03-25 | Vinit Singh; Jacob Babcock; Christine A. Frysz |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 208 | VERTICALLY INTEGRATED SYSTEMS | US14041745 | 2013-09-30 | US20140034104A1 | 2014-02-06 | Alan J. O'DONNELL; Santiago IRIARTE; Mark J. MURPHY; Colin G. LYDEN; Gary CASEY; Eoin Edward ENGLISH |
| Embodiments of the present invention provide an integrated circuit system including a first active layer fabricated on a front side of a semiconductor die and a second pre-fabricated layer on a back side of the semiconductor die and having electrical components embodied therein, wherein the electrical components include at least one discrete passive component. The integrated circuit system also includes at least one electrical path coupling the first active layer and the second pre-fabricated layer. | ||||||
| 209 | Vertically integrated systems | US12975847 | 2010-12-22 | US08569861B2 | 2013-10-29 | Alan O'Donnell; Santiago Iriarte; Mark J. Murphy; Colin Lyden; Gary Casey; Eoin Edward English |
| Embodiments of the present invention provide an integrated circuit system including a first active layer fabricated on a front side of a semiconductor die and a second pre-fabricated layer on a back side of the semiconductor die and having electrical components embodied therein, wherein the electrical components include at least one discrete passive component. The integrated circuit system also includes at least one electrical path coupling the first active layer and the second pre-fabricated layer. | ||||||
| 210 | SHIELDED TORQUE CARRIER FOR A PASSIVE ELECTRONIC COMPONENT IN AN ACTIVE MEDICAL DEVICE IMPLANTABLE LEAD | US13860191 | 2013-04-10 | US20130226273A1 | 2013-08-29 | Warren S. Dabney; Robert Shawn Johnson; Holly Noelle Moschiano; Robert A. Stevenson; Henry R. Halperin; Albert C. Lardo; Kishore Kumar Kondabatni |
| A shielded component or network for an active medical device (AMD) implantable lead includes (1) an implantable lead having a length extending from a proximal end to a distal end, all external of an AMD housing, (2) a passive component or network disposed somewhere along the length of the implantable lead, the passive component or network including at least one inductive component having a first inductive value, and (3) an electromagnetic shield substantially surrounding the inductive component or the passive network. The first inductive value of the inductive component is adjusted to a account for a shift in its inductance to a second inductive value when shielded. | ||||||
| 211 | MULTI-LAYER-MULTI-TURN HIGH EFFICIENCY INDUCTORS WITH CAVITY STRUCTURES | US13797415 | 2013-03-12 | US20130200976A1 | 2013-08-08 | Vinit SINGH; Jacob BABCOCK; Christine A. FRYSZ |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 212 | MULTI-LAYER-MULTI-TURN STRUCTURE FOR TUNABLE HIGH EFFICIENCY INDUCTORS | US13797437 | 2013-03-12 | US20130200969A1 | 2013-08-08 | Vinit SINGH; Jacob BABCOCK; Christine A. FRYSZ |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 213 | MULTI-LAYER-MULTI-TURN STRUCTURE FOR HIGH EFFICIENCY INDUCTORS | US13797387 | 2013-03-12 | US20130200968A1 | 2013-08-08 | Vinit SINGH; Jacob BABCOCK; Christine A. FRYSZ |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 214 | MULTI-LAYER-MULTI-TURN HIGH EFFICIENCY INDUCTORS FOR AN INDUCTION HEATING SYSTEM | US13797593 | 2013-03-12 | US20130200070A1 | 2013-08-08 | Vinit SINGH; Jacob BABCOCK; Christine A. FRYSZ |
| A multi-layer, multi-turn structure for an inductor having a plurality of conductor layers separated by layers of insulator is described. The inductor further comprises a connector electrically connected between the conductor layers. The structure of the inductor may comprise a cavity therewithin. The structure of the inductor constructed such that electrical resistance is reduced therewithin, thus increasing the efficiency of the inductor. The inductor is particularly useful at operating within the radio frequency range and greater. | ||||||
| 215 | Shielded network for an active medical device implantable lead | US12891292 | 2010-09-27 | US08437865B2 | 2013-05-07 | Warren S. Dabney; Robert Shawn Johnson; Holly Noelle Mosciano; Robert A. Stevenson; Henry R. Halperin; Albert C. Lardo; Kishore Kumar Kondabatni |
| A shielded component or network for an active medical device (AMD) implantable lead includes (1) an implantable lead having a length extending from a proximal end to a distal end, all external of an AMD housing, (2) a passive component or network disposed somewhere along the length of the implantable lead, the passive component or network including at least one inductive component having a first inductive value, and (3) an electromagnetic shield substantially surrounding the inductive component or the passive network. The first inductive value of the inductive component is adjusted to a account for a shift in its inductance to a second inductive value when shielded. | ||||||
| 216 | INDUCTOR COMPRISING ARRAYED CAPACITORS | US13641764 | 2011-04-14 | US20130106538A1 | 2013-05-02 | Satyajit Sahu; Anirban Bandyopadhyay; Daisuke Fujita |
| A spiral capacitor-inductor device in which an array of unit capacitors 101 is arranged in a loop along the length is provided as the fourth circuit element. An input signal is applied to one end of the array of the unit capacitors, an output signal is taken out from the other end, an electric charge stored in each unit capacitor increases or decreases in accordance with increase or decrease in the bias applied to the device, the increase or decrease in the electric charge causes the current of the loop to increase or decrease, and, as a result, the magnetic flux 103 generated in the device varies. Accordingly, the fourth circuit element is provided that follows after an inductor, a capacitor, and a resistor is provided in which the electric charge stored determines the magnitude of its magnetic flux. | ||||||
| 217 | System Comprising a Multi-Layer-Multi-Turn Structure for High Efficiency Wireless Communication | US13233624 | 2011-09-15 | US20130069749A1 | 2013-03-21 | Vinit Singh; Christine A. Frysz |
| A structure for wireless communication having a plurality of conductor layers, an insulator layer separating each of the conductor layers, and at least one connector connecting two of the conductor layers wherein an electrical resistance is reduced when an electrical signal is induced in the resonator at a predetermined frequency. | ||||||
| 218 | Implantable lead for an active medical device having an inductor design minimizing eddy current losses | US13042177 | 2011-03-07 | US08260435B2 | 2012-09-04 | Robert Shawn Johnson; Warren S. Dabney; Holly Noelle Moschiano; Robert A. Stevenson |
| A shielded component or network for an active medical device (AMD) implantable lead includes an implantable lead having a length extending from a proximal end to a distal end, all external of an AMD housing, and a passive component or network disposed somewhere along the length of the implantable lead. The passive component or network including at least one inductive component having a primary magnetic field line axis. A conductive shield or housing having a primary longitudinal axis substantially surrounds the inductive component or the passive network. The inductive component's magnetic field line axis is oriented substantially orthogonally to the primary longitudinal axis of the conductive shield or housing. | ||||||
| 219 | Load-carrying body for reducing torsional and tensile loading on electronic components in an implantable medical electrical lead | US12914048 | 2010-10-28 | US08244373B1 | 2012-08-14 | Ryan Thomas Bauer; Warren S. Dabney; Robert A. Stevenson |
| A load-carrying body for reducing torsional and tensile loading on electrical components in an implantable medical electrical lead includes an electronic component disposed in-line with the implantable medical electrical lead, and a casing for the electronic component. The electronic component has a proximal end conductively coupled to a lead conductor and a distal end conductively coupled to a lead electrode. The casing is mechanically coupled to the lead so as to isolate the electrical component from torque or tensile loads applied to the lead, the lead electrode, or both. | ||||||
| 220 | Current sensing inductor and a circuit thereof | US12289558 | 2008-10-30 | US08242771B2 | 2012-08-14 | Chi Hung Cheung |
| An inductor design having a detection winding which is magnetically coupled to the existing winding and its induction voltage is used to cancel that of the existing winding. Having the induction voltage cancelled, the voltage across the existing winding represents a resistive voltage drop of the existing winding current. The detection winding is furthermore built with a non-inductive portion having a significantly higher DC resistance in proportion to that of the existing winding. This resistance proportion is insensitive against temperature variations when both the existing and the detection windings are built with the same material and subjected to the same environment. A reference current is fed through the detection winding to produce a reference resistive voltage drop which is used to cancel the resistive voltage drop across the existing winding. When a precise cancellation occurs, the existing winding current is known to be in exact proportion to the reference current. | ||||||
QQ群二维码
意见反馈
意见反馈