Class / Patent application number | Description | Number of patent applications / Date published |
365175000 | Diodes | 18 |
20080239801 | Load Management for Memory Device - Methods and apparatus for managing electrical loads of electronic devices are disclosed. According to one embodiment, a current load imposed by an electronic device, such as a memory device (or memory system), can be measured. Then, using the measured current load, the memory device can determine whether (and to what extent) operational performance should be limited. By limiting operational performance, the memory device is able to limit its current load so as to satisfy a specification criterion or other requirement. The electrical load management is well suited for use in portable memory products (e.g., memory cards) to manage current loads being drawn. | 10-02-2008 |
20080239802 | Device with Load-Based Voltage Generation - Method and device for providing voltage generation with load-based control are disclosed. The voltage generation can be provided within an electronic device, such as a memory system that provides data storage. In one embodiment, an electrical load imposed on a generated voltage can be monitored and used to dynamically control strength of the generated voltage. For example, for greater electrical loads, the generated voltage can be provided with a greater strength, and for lesser electrical loads, the generated voltage can be provided with a lesser strength. By compensating the generated voltage for the nature of the imposed electrical load, the generated voltage can be provided in a stable manner across a significant range of loads. In the case of a memory system, stability in the generated voltage provides for reduced voltage ripple and thus improved sensing margins. The voltage generation is well suited for use in portable memory products (e.g., memory cards) to generate one or more internal voltages. | 10-02-2008 |
20080316808 | Nonvolatile memory device containing carbon or nitrogen doped diode - A nonvolatile memory device includes at least one nonvolatile memory cell which comprises a silicon, germanium or silicon-germanium diode which is doped with at least one of carbon or nitrogen in a concentration greater than an unavoidable impurity level concentration. | 12-25-2008 |
20080316809 | High forward current diodes for reverse write 3D cell - A nonvolatile memory device includes at least one memory cell which comprises a diode and a metal oxide antifuse dielectric layer, and a first electrode and a second electrode electrically contacting the at least one memory cell. In use, the diode acts as a read/write element of the memory cell by switching from a first resistivity state to a second resistivity state different from the first resistivity state in response to an applied bias. | 12-25-2008 |
20090046503 | Enhanced Gated Diode Memory Cells - A memory cell for use in an integrated circuit comprises a read transistor and a gated diode. The read transistor has a source terminal. The gated diode has a gate terminal in signal communication with the read transistor. A variable source voltage acts on the source terminal of the read transistor when the memory cell is in operation. The variable source voltage is temporarily altered when the memory cell is read. For example, the source voltage may be reduced when the read transistor is implemented using an N-type transistor and increased when the read transistor is implemented using P-type transistor. This acts to impart the memory cell with faster read speed, higher read margin, and lower standby current. | 02-19-2009 |
20090168507 | Method of programming cross-point diode memory array - A method of programming a nonvolatile memory array including a plurality of nonvolatile memory cells, a plurality of bit lines, and a plurality of word lines, wherein each memory cell comprises a diode, or a diode and a resistivity switching element is disclosed. The method includes both bias programming the memory cells of the device. | 07-02-2009 |
20090285018 | Gated Diode Memory Cells - A gated diode memory cell is provided, including one or more transistors, such as field effect transistors (“FETs”), and a gated diode in signal communication with the FETs such that the gate of the gated diode is in signal communication with the source of a first FET, wherein the gate of the gated diode forms one terminal of the storage cell and the source of the gated diode forms another terminal of the storage cell, the drain of the first FET being in signal communication with a bitline (“BL”) and the gate of the first FET being in signal communication with a write wordline (“WLw”), and the source of the gated diode being in signal communication with a read wordline (“WLr”). | 11-19-2009 |
20100149865 | SCR MATRIX STORAGE DEVICE - One of the simplest forms of data storage devices is the diode array storage device. However, a problem with diode array storage devices is that as the size of the array increases, the number of non-addressed diodes connected between a given selected row or column of the array and the non-addressed columns or rows of the array, respectively, also becomes very large. While the leakage current through any one non-addressed diode on the selected row or column will have little impact on the operation of the device, the cumulative leakage through multiple thousands of non-addressed diodes can become significant. This aggregate leakage current can become great enough that the output voltage can be shifted such that the threshold for distinguishing between a one state and a zero state of the addressed diode location can become obscured and can result in a misreading of the addressed diode location. The present invention is a means to manage the leakage currents in a diode array storage device. This is accomplished by actively changing the forward voltage of the diodes in the storage array such that a diode connected to the selected row line but that is not connected to the selected column line is in its high impedance state and a diode connected to the selected column line but that is not connected to the selected row line is in its high impedance state; only a diode that is connected to both the selected row line and the selected column line will switch to its low impedance state. The present invention is an enhancement to all types of arrays of diodes or arrays of other nonlinear conducting elements including: storage devices, programmable logic devices, display arrays, sensor arrays, and many others. | 06-17-2010 |
20100208517 | PIN DIODE DEVICE AND ARCHITECTURE - A memory architecture that employs one or more semiconductor PIN diodes is provided. The memory employs a substrate that includes a buried bit/word line and a PIN diode. The PIN diode includes a non-intrinsic semiconductor region, a portion of the bit/word line, and an intrinsic semiconductor region positioned between the non-intrinsic region and the portion of the bit/word line. | 08-19-2010 |
20110019468 | NON-LINEAR CONDUCTOR MEMORY - A high-speed, low-power memory device comprises an array of non-linear conductors wherein the storage, address decoding, and output detection are all accomplished with diodes or other non-linear conductors. In various embodiments, the row and column resistors are switchable between a high resistance when connected to a row or column that is non-selected, and a low resistance when connected to the selected row and column. | 01-27-2011 |
20110026323 | Gated Diode Memory Cells - A gated diode memory cell is provided, including one or more transistors, such as field effect transistors (“FETs”), and a gated diode in signal communication with the FETs such that the gate of the gated diode is in signal communication with the source of a first FET, wherein the gate of the gated diode forms one terminal of the storage cell and the source of the gated diode forms another terminal of the storage cell, the drain of the first FET being in signal communication with a bitline (“BL”) and the gate of the first FET being in signal communication with a write wordline (“WLw”), and the source of the gated diode being in signal communication with a read wordline (“WLr”). | 02-03-2011 |
20110222337 | FLOATING-BODY/GATE DRAM CELL - Memory cell structures and biasing schemes are provided. Certain embodiments pertain to a modified floating-body gate cell, which can provide improved retention times. In one embodiment, a gated diode is used to drive the gate of a second transistor structure of a cell. In another embodiment, a body-tied-source (BTS) field effect transistor is used to drive the gate of the second transistor structure of a cell. | 09-15-2011 |
20110267880 | MEMORY CIRCUITS HAVING A DIODE-CONNECTED TRANSISTOR WITH BACK-BIASED CONTROL - A memory circuit includes at least one memory array. At least one sleep transistor is electrically coupled between the at least one memory array and a first power line for providing a first power voltage. At least one diode-connected transistor is electrically coupled between the at least one memory array and the first power line. A back-bias circuit is electrically coupled with a bulk of the at least one diode-connected transistor. | 11-03-2011 |
20110273930 | Diode Memory - A diode memory device has an intermediate structure between the two terminals, such as a p terminal and the n terminal. | 11-10-2011 |
20110292723 | DRAM CELL UTILIZING FLOATING BODY EFFECT AND MANUFACTURING METHOD THEREOF - The present invention discloses a DRAM cell utilizing floating body effect and a manufacturing method thereof. The DRAM cell includes a P type semiconductor region provided on a buried oxide layer, an N type semiconductor region provided on the P type semiconductor region, a gate region provided on the N type semiconductor region, and an electrical isolation region surrounding the P type semiconductor region and the N type semiconductor region. A diode of floating body effect is taken as a storage node. Via a tunneling effect between bands, electrons gather in the floating body, which is defined as a first storage state; via forward bias of PN junction, electrons are emitted out from the floating body or holes are injected into the floating body, which is defined as a second storage state. The present invention provides a highly efficient DRAM cell utilizing floating body effect with high density, which has low power consumption, has simple manufacturing process, and is compatible to the conventional CMOS and conventional logic circuit manufacturing process. | 12-01-2011 |
20120300544 | GATED DIODE MEMORY CELLS - A gated diode memory cell is provided, including one or more transistors, such as field effect transistors (“FETs”), and a gated diode in signal communication with the FETs such that the gate of the gated diode is in signal communication with the source of a first FET, wherein the gate of the gated diode forms one terminal of the storage cell and the source of the gated diode forms another terminal of the storage cell, the drain of the first FET being in signal communication with a bitline (“BL”) and the gate of the first FET being in signal communication with a write wordline (“WLw”), and the source of the gated diode being in signal communication with a read wordline (“WLr”). | 11-29-2012 |
20130286728 | NONVOLATILE MEMORY CELL OPERATING BY INCREASING ORDER IN POLYCRYSTALLINE SEMICONDUCTOR MATERIAL - A memory cell is provided that includes a first conductor, a second conductor, and a semiconductor junction diode between the first and second conductors. The semiconductor junction diode is not in contact with a material having a lattice mismatch of less than 12 percent with the semiconductor junction diode. Numerous other aspects are provided. | 10-31-2013 |
20150016185 | Electro-Mechanical Diode Non-Volatile Memory Cell For Cross-Point Memory Arrays - A non-volatile electro-mechanical diode memory cell is described for implementation of compact (4F | 01-15-2015 |