Abstract: A method of controlling gate induced drain leakage current of a transistor is disclosed. The method includes forming a dielectric region (516) on a surface of a substrate having a first concentration of a first conductivity type (P-well). A gate region (500) having a length and a width is formed on the dielectric region. Source (512) and drain (504) regions having a second conductivity type (N+) are formed in the substrate on opposite sides of the gate region. A first impurity region (508) having the first conductivity type (P+) is formed adjacent the source. The first impurity region has a second concentration greater than the first concentration.

Abstract: The present invention provides a thermostatic biasing controller for use with an integrated circuit. In one embodiment, the thermostatic biasing controller includes a temperature sensing unit configured to determine an operating temperature of the integrated circuit. Additionally, the thermostatic biasing controller also includes a voltage controlling unit coupled to the temperature sensing unit and configured to provide a back-bias voltage corresponding to the operating temperature based on reducing a quiescent current of the integrated circuit.

Abstract: A method of controlling gate induced drain leakage current of a transistor is disclosed. The method includes forming a dielectric region (516) on a surface of a substrate having a first concentration of a first conductivity type (P-well). A gate region (500) having a length and a width is formed on the dielectric region. Source (512) and drain (504) regions having a second conductivity type (N+) are formed in the substrate on opposite sides of the gate region. A first impurity region (508) having the first conductivity type (P+) is formed adjacent the source. The first impurity region has a second concentration greater than the first concentration.

Abstract: An integrated circuit including an array of SRAM cells containing a write port with a write word line and two read buffers with read word lines. The write port includes passgate transistors connected to each data node of the SRAM cell. A process of operating the integrated circuit in which source nodes of read buffer driver transistors are biased during a read operation. A process of operating the integrated circuit in which source nodes of read buffer driver transistors are floated during a read operation. A process of operating the integrated circuit in which the write port and the read ports share data lines and the source nodes of read buffer driver transistors are floated during a write operation.

Abstract: An integrated circuit with SRAM cells containing dual passgate transistors and a read buffer, all connected to one word line is disclosed. The read buffer and one passgate transistor may be variously configured to a separate read data line and write data line, or a combined data line, in different embodiments. The read buffer in addressed SRAM cells may be biased during read operations. The read buffer in half-addressed SRAM cells may be biased or floated, depending on the configuration of the read data line and the write data line. The read buffer in addressed and half-addressed SRAM cells may be biased or floated, depending on the configuration of the read data line and the write data line.

Abstract: A first integrated circuit containing a single sided write SRAM cell array, each SRAM cell having a bit passgate and an auxiliary bit-bar driver transistor. A process of operating the first integrated circuit including a single sided read operation in which source nodes of the auxiliary drivers in both addressed cells and half-addressed cells are floated. A second integrated circuit containing an SRAM cell array, in which each SRAM cell includes a bit-side write passgate, a bit-bar-side read passgate and a bit-bar auxiliary driver transistor. A process of operating the second integrated circuit including a single sided read operation in which source nodes of the auxiliary drivers in both addressed cells and half-addressed cells are biased to a low bias voltage.

Abstract: An integrated circuit containing an SRAM cell array in which each SRAM cell includes an auxiliary NMOS driver or PMOS load transistor plus a bit-side passgate transistor and a bit-bar-side passgate transistor. An integrated circuit containing an SRAM cell array in which each SRAM cell includes an auxiliary PMOS driver or NMOS load transistor plus a bit-side passgate transistor and a bit-bar-side passgate transistor. A process of operating an integrated circuit containing an SRAM cell array in which each SRAM cell includes an auxiliary NMOS driver or PMOS load transistor plus a bit-side passgate transistor and a bit-bar-side passgate transistor. A process of operating an integrated circuit containing an SRAM cell array in which each SRAM cell includes an auxiliary PMOS driver or NMOS load transistor plus a bit-side passgate transistor and a bit-bar-side passgate transistor.

Abstract: An integrated circuit containing SRAM cells with auxiliary load transistors on each data node. The integrated circuit also contains circuitry so that auxiliary load transistors in addressed SRAM cells may be biased independently of half-addressed cells. A process of operating an integrated circuit containing SRAM cells with auxiliary load transistors on each data node. The process includes biasing the auxiliary load transistors in addressed SRAM cells independently of half-addressed cells.

Abstract: A dual port SRAM cell includes an auxiliary driver transistor on each data node. The SRAM cell is capable of single sided write to each data node. The auxiliary driver transistors in addressed cells may be biased independently of half-addressed cells. During write and read operations, the auxiliary driver transistors may be floated or biased. Auxiliary driver transistors in half-addressed SRAM cells may be biased. During standby modes, the auxiliary driver transistors may be floated. During sleep modes, the auxiliary driver transistors may be biased at reduced voltages. The auxiliary driver transistors in each cell may be independent or may have a common source node within each cell. Additional single sided write ports and read buffers may be added. A process of operating an integrated circuit that includes performing a single-sided write bit-side low, a single-sided write bit-side high, and a read bit-side operation.

Abstract: An SRAM cell containing an auxiliary driver transistor is configured for a single sided write operation. The auxiliary driver transistor may be added to a 5-transistor single-sided-write SRAM cell or to a 7-transistor single-sided-write SRAM cell. The SRAM cell may also include a read buffer. During read operations, the auxiliary drivers are biased. During write operations, the auxiliary drivers in half-addressed SRAM cells are biased and the auxiliary drivers in the addressed SRAM cells may be floated or biased.

Abstract: Methods for measuring the read margin, write margin, and stability margin of SRAM bits with operational circuitry that includes effects of the SRAM array architecture and circuit design. In addition, methods for measuring the read margin, write margin, and stability margin of SRAM that excludes the effects of SRAM array architecture and circuit design.

Abstract: A 3T DRAM cell includes a first transistor having a first control element connected as a storage node and a second transistor connected between the first transistor and a read bit line having a second control element connected to a read word line. The 3T DRAM cell also includes a third transistor connected between the storage node and a write bit line having a third control element connected to a write word line. Additionally, the DRAM cell includes a supplemental capacitance connected to the storage node and configured to extend a refresh interval of the 3T DRAM cell. A method of operating an integrated circuit having a 3T DRAM cell includes providing a memory state on a storage node of the 3T DRAM cell and extending a refresh interval of the memory state with a supplemental capacitance added to the storage node.

Abstract: An array with cells that have adjacent similar structures that are displaced from each other across a common cell border in a direction that is not perpendicular to the cell border thus avoiding an across cell border design rule violation between the adjacent similar structures. A method of forming reduced area memory arrays by displacing adjacent similar structures along a common cell border. A method of building arrays using conventional array building software by forming unit pairs with cells that are not identical and are not mirror images or rotated versions of each other.

Abstract: An integrated circuit containing a SRAM memory with SRAM bits optimized to have a lower minimum read voltage than the minimum write voltage. A method for reading a SRAM memory bit using a read voltage that is lower than the write voltage.

Abstract: An integrated circuit containing an SRAM that provides a switch to decouple the SRAM wordline voltage from the SRAM array voltage during screening and that also provides different wordline and array voltages during a portion of the SRAM bit screening test. A method for screening SRAM bits in an SRAM array in which the wordline voltage is different than the array voltage during a portion of the screening test.

Abstract: A static random-access memory (SRAM) and a method of controlling bit line voltage. In one embodiment, the SRAM includes: (1) an array of SRAM cells organized in rows and columns, (2) bit lines associated with the columns, (3) a high voltage power supply configured to supply a high supply voltage, (4) a low voltage power supply configured to supply a low supply voltage, (5) bit line precharge circuitry configured to precharge at least one of the bit lines to a first voltage and (6) standby circuitry configured to maintain a voltage of the at least one bit line at least a second voltage, the second voltage being lower than the first voltage and higher than the low supply voltage.

Abstract: An integrated circuit having an SRAM array includes SRAM cells arranged in rows and columns, and a global read circuit connected to globally read SRAM cells corresponding to accessed rows and columns of the SRAM array. The SRAM array also includes a separate, local sense and feedback circuit connected to a local column of the SRAM array, wherein a sensing portion indicates a memory state of an SRAM cell in an accessed row of the local column and a feedback portion rewrites the memory state back into the SRAM cell. Additionally, a method of operating an integrated circuit having an SRAM array includes providing an SRAM cell in an addressed condition of the SRAM array. The method also includes locally sensing a current memory state of the SRAM cell and locally feeding back to the SRAM cell to retain the memory state during the addressed condition.

Abstract: An integrated circuit having a static random access memory (SRAM) includes an array of SRAM cells arranged in rows and columns having a write word line and a read/write word line connected to provide row access to the array of SRAM cells. The SRAM also includes a coupling capacitance connected between the write word line and a detachable allocation of the read/write word line as well as an overdrive module connected to charge the coupling capacitance and provide an overdrive voltage on the detachable allocation of the read/write word line during activation of the write word line. A method of operating an integrated circuit having an SRAM includes providing an overdrive voltage on the detachable allocation of the read/write word line corresponding to a charge redistribution across the coupling capacitance during part of a write cycle.

Abstract: A body bias coordinator is provided for use with a transistor employing a body region. In one example, the body bias coordinator includes a control unit configured to control the transistor and make it operable to provide a virtual supply voltage from a source voltage during activation of the transistor. The body bias coordinator also includes a connection unit coupled to the control unit and configured to connect the body region to the virtual supply voltage during activation of the transistor. In an alternative embodiment, the connection unit is further configured to connect the body region to another voltage during non-activation of the transistor.

Abstract: The present invention provides a thermostatic bias controller for use with a memory array. The thermostatic bias controller includes a temperature sensing circuit configured to sense a temperature associated with the memory array. The thermostatic bias controller also includes a voltage control circuit coupled to the temperature sensing circuit and configured to provide a bias voltage to at least one back-gate of the memory array based on the temperature.