| Patent application number | Description | Published |
|---|
| 20080237721 | STRUCTURE AND CIRCUIT TECHNIQUE FOR UNIFORM TRIGGERING OF MULTIFINGER SEMICONDUCTOR DEVICES WITH TUNABLE TRIGGER VOLTAGE - An external current injection source is provided to individual fingers of a multi-finger semiconductor device to provide the same trigger voltage across the multiple fingers. For example, the external injection current is supplied to the body of a MOSFET or the gate of a thyristor. The magnitude of the supplied current from each external current injection source is adjusted so that each finger has the same trigger voltage. The external current supply circuit may comprise diodes or an RC triggered MOSFET. The components of the external current supply circuit may be tuned to achieve a desired predetermined trigger voltage across all fingers of the multi-finger semiconductor device. | 10-02-2008 |
| 20080308837 | VERTICAL CURRENT CONTROLLED SILICON ON INSULATOR (SOI) DEVICE SUCH AS A SILICON CONTROLLED RECTIFIER AND METHOD OF FORMING VERTICAL SOI CURRENT CONTROLLED DEVICES - A Silicon on Insulator (SOI) Integrated Circuit (IC) chip with devices such as a vertical Silicon Controlled Rectifier (SCR), vertical bipolar transistors, a vertical capacitor, a resistor and/or a vertical pinch resistor and method of making the device(s). The devices are formed in a seed hole through the SOI surface layer and insulator layer to the substrate. A buried diffusion, e.g., N-type, is formed through the seed hole in the substrate. A doped epitaxial layer is formed on the buried diffusion and may include multiple doped layers, e.g., a P-type layer and an N-type layer. Polysilicon, e.g., P-type, may be formed on the doped epitaxial layer. Contacts to the buried diffusion are formed in a contact liner. | 12-18-2008 |
| 20090007051 | SELECTABLE DEVICE OPTIONS FOR CHARACTERIZING SEMICONDUCTOR DEVICES - A system, method and program product that allows multiple devices to be placed between pads such that a Back End Of Line (BEOL) mask change can be used to select different device options. A system is disclosed for implementing a testsite for characterizing devices in an integrated circuit technology, and includes: a system for designing a plurality of device options for a set of chip pads; a system for designing a pseudo wiring layout for each of the plurality of device options; a system for selecting one of the device options; a system for mapping the pseudo wiring layout for a selected device option to a predetermined design level; and a system for outputting a configured mask design at the predetermined design level having a wiring layout mapped for the selected device option. | 01-01-2009 |
| 20090108289 | DESIGN STRUCTURE FOR UNIFORM TRIGGERING OF MULTIFINGER SEMICONDUCTOR DEVICES WITH TUNABLE TRIGGER VOLTAGE - A design structure for a circuit providing the same trigger voltage across the multiple fingers is provided, which comprises a data representing an external current injection source connected to individual fingers of a multi-finger semiconductor device. For example, the external injection current is supplied to the body of a MOSFET or the gate of a thyristor. The magnitude of the supplied current from each external current injection source is adjusted so that each finger has the same trigger voltage. The external current supply circuit may comprise diodes or an RC triggered MOSFET. The components of the external current supply circuit may be tuned to achieve a desired predetermined trigger voltage across all fingers of the multi-finger semiconductor device. | 04-30-2009 |
| 20090160013 | SEMICONDUCTOR DEVICE HEAT DISSIPATION STRUCTURE - A heat generating component of a semiconductor device is located between two heavily doped semiconductor regions in a semiconductor substrate. The heat generating component may be a middle portion of a diode having a light doping, a lightly doped p-n junction between a cathode and anode of a silicon controlled rectifier, or a resistive portion of a doped semiconductor resistor. At least one thermally conductive via comprising a metal or a non-metallic conductive material is place directly on the heat generating component. Alternatively, a thin dielectric layer may be formed between the heat generating component and the at least one thermally conductive via. The at least one thermally conductive via may, or may not, be connected to a back-end-of-line metal wire, which may be connected to higher level of metal wiring or to a handle substrate through a buried insulator layer. | 06-25-2009 |
| 20090256202 | SEMICONDUCTOR-ON-INSULATOR DEVICE STRUCTURES WITH A BODY-TO-SUBSTRATE CONNECTION FOR ENHANCED ELECTROSTATIC DISCHARGE PROTECTION, AND DESIGN STRUCTURES FOR SUCH SEMICONDUCTOR-ON-INSULATOR DEVICE STRUCTURES - Semiconductor-on-insulator device structures with enhanced electrostatic discharge protection, and design structures for an integrated circuit with device structures exhibiting enhanced electrostatic discharge protection. A device is formed in a body region of a device layer of a semiconductor-on-insulator substrate, which is bounded by an inner peripheral sidewall of an annular dielectric-filled isolation structure that extends from a top surface of the device layer to the insulating layer of the semiconductor-on-insulator substrate. An annular conductive interconnect extends through the body region and the insulating layer to connect the body region with the bulk wafer of the semiconductor-on-insulator substrate. The annular conductive interconnect is disposed inside the inner peripheral sidewall of the isolation structure, which annularly encircles the body region. | 10-15-2009 |
| 20090302416 | Programmable Electrical Fuse - The present invention relates to e-fuse devices, and more particularly to a device and method of forming an e-fuse device, the method comprising providing a first conductive layer connected to a second conductive layer, the first and second conductive layers separated by a barrier layer having a first diffusivity different than a second diffusivity of the first conductive layer. A void is created in the first conductive layer by driving an electrical current through the e-fuse device. | 12-10-2009 |
| 20110001551 | CIRCUIT STRUCTURE AND METHOD FOR PROGRAMMING AND RE-PROGRAMMING A LOW POWER, MULTIPLE STATES, ELECTRONIC FUSE (E-FUSE) - Disclosed are embodiments of an e-fuse programming/re-programming circuit. In one embodiment, the e-fuse has two short high atomic diffusion resistance conductor layers positioned on opposite sides and at a same end of a long low atomic diffusion resistance conductor layer. A voltage source is used to vary the polarity and, optionally, the magnitude of voltage applied to the terminals in order to control bi-directional flow of electrons within the long conductor layer and, thereby formation of opens and/or shorts at the long conductor layer-short conductor layer interfaces. The formation of such opens and/or shorts can be used to achieve different programming states. Other circuit structure embodiments incorporate e-fuses with additional conductor layers and additional terminals so as to allow for even more programming states. Also disclosed are embodiments of associated e-fuse programming and re-programming methods. | 01-06-2011 |
| 20110049683 | STRUCTURES, METHODS AND APPLICATIONS FOR ELECTRICAL PULSE ANNEAL PROCESSES - Structures and methods are provided for nanosecond electrical pulse anneal processes. The method of forming an electrostatic discharge (ESD) N+/P+ structure includes forming an N+ diffusion on a substrate and a P+ diffusion on the substrate. The P+ diffusion is in electrical contact with the N+ diffusion. The method further includes forming a device between the N+ diffusion and the P+ diffusion. A method of annealing a structure or material includes applying an electrical pulse across an electrostatic discharge (ESD) N+/P+ structure for a plurality of nanoseconds. | 03-03-2011 |
