Abstract: A memory circuit includes at least one bit cell that receives a word line, complementary bit lines and an array supply voltage and a word line suppression circuit. The word line suppression circuit includes two PFETs with their drains connected to the word line and their sources connected to the array supply voltage and an NFET with its source connected to ground and its drain connected to the word line. The NFET is inactivated before the PFETs are activated. One of the PFETs is activated before the other PFET is activated so as to control the slew rate of the word line and improve the static noise margin of the at least one bit cell.

Abstract: A memory circuit includes a bit cell that receives a word line, complementary bit lines and an array supply voltage; a word line driver coupled to the word line, the word line driver receiving the array supply voltage; and a word line suppression circuit coupled to the word line. The word line suppression circuit includes a diode and a first switch coupled in series and a second switch. The switches are responsive to a control signal. The word line suppression circuit limits a word line voltage to a value lower than the array supply voltage such that the static noise margin (SNM) of the bit cell is increased.

Abstract: A two-bit read-only-memory (ROM) cell and method of sensing its data state. Each ROM cell in an array includes a single n-channel metal-oxide-semiconductor (MOS) transistor with a source biased to a reference voltage, and its drain connected by a contact or via to one or none of first, second, and third bit lines associated with its column in the array. Each row in the array is associated with a word line serving as the transistor gates for the cells in that row. In response to a column address, a column select circuit selects one pair of the three bit lines to be applied to a sense line in wired-NOR fashion for sensing.

Abstract: A memory circuit includes a bit cell that receives a word line, complementary bit lines and an array supply voltage; a word line driver coupled to the word line, the word line driver receiving one of the array supply voltage and a periphery supply voltage; and a word line suppression circuit coupled to the word line. The word line suppression circuit includes a diode and a switch coupled in series. The switch is responsive to the array supply voltage. The word line suppression circuit limits a word line voltage to a value lower than the array supply voltage such that the static noise margin (SNM) of the bit cell is increased.

Abstract: A memory circuit includes a bit cell that receives a word line, complementary bit lines and an array supply voltage; a word line driver coupled to the word line, the word line driver receiving one of the array supply voltage and a periphery supply voltage; and a word line suppression circuit coupled to the word line. The word line suppression circuit includes a diode and a switch coupled in series. The switch is responsive to the array supply voltage. The word line suppression circuit limits a word line voltage to a value lower than the array supply voltage such that the static noise margin (SNM) of the bit cell is increased.

Abstract: A memory circuit includes a bit cell that receives a word line, complementary bit lines and an array supply voltage; a word line driver coupled to the word line, the word line driver receiving one of the array supply voltage and a periphery supply voltage; and a word line suppression circuit coupled to the word line. The word line suppression circuit includes a diode and a switch coupled in series. The switch is responsive to the array supply voltage. The word line suppression circuit limits a word line voltage to a value lower than the array supply voltage such that the static noise margin (SNM) of the bit cell is increased.

Abstract: A two-bit read-only-memory (ROM) cell and method of sensing its data state. Each ROM cell in an array includes a single n-channel metal-oxide-semiconductor (MOS) transistor with a source biased to a reference voltage, and its drain connected by a contact or via to one or none of first, second, and third bit lines associated with its column in the array. Each row in the array is associated with a word line serving as the transistor gates for the cells in that row. In response to a column address, a column select circuit selects one pair of the three bit lines to be applied to a sense line in wired-NOR fashion for sensing.

Abstract: An FRAM device can comprise a sense amplifier, at least a first bitcell, a first control line, and a second control line. The first bitcell can have a bit line that connects to the sense amplifier via a first isolator and a complimentary bit line that connects to the sense amplifier via a second isolator that is different from the first isolator. The first control line can connect to and control the aforementioned first isolator. And the second control line can connect to and control the second isolator such that the second isolator is independently controlled with respect to the first isolator to facilitate testing the device.

Abstract: An FRAM device can comprise a sense amplifier and at least a first bitcell. The first bitcell can have a bit line and a complimentary bit line that connects to the sense amplifier. A first precharge circuit responds to a first control signal during a test mode of operation to precharge the bit line with respect to a first voltage while a second precharge circuit responds to a second control signal (that is different from the first control signal) during the test mode of operation to precharge the complimentary bit line with respect to a test voltage that is different than the first voltage (such as, but not limited to, a test voltage of choice such as a voltage that is greater than ground but less than the first voltage).

Abstract: A ferroelectric memory device includes a shunt switch configured to short both sides of the ferroelectric capacitor of the ferroelectric memory device. The shunt switch is configured therefore to remove excess charge from around the ferroelectric capacitor prior to or after reading data from the ferroelectric capacitor. By one approach, the shunt switch is connected to operate in reaction to signals from the same line that controls accessing the ferroelectric capacitor. So configured, the high performance cycle time of the ferroelectric memory device is reduced by eliminating delays used to otherwise drain excess charge from around the ferroelectric capacitor, for example by applying a precharge voltage. The shunt switch also improves reliability of the ferroelectric memory device by ensuring that excess charge does not affect the reading of the ferroelectric capacitor during a read cycle.

Abstract: A self-timed sense amplifier read buffer pulls down a pre-charged high global bit line, which then feeds data into a tri state write back buffer that is connected directly to the bit line. The bit line provides charge to a ferroelectric capacitor to write a logical “one” or “zero” while by-passing an isolator switch disposed between the sense amplifier and the ferroelectric capacitor. Because the sense amplifier uses grounded bit line sensing, the read buffer will not start pulling down the global bit line until after the sense amplifier signal amplification, which makes the timing of the control signal for this read buffer non-critical. The write-back buffer enable timing is also self-timed off of the sense amplifier. Therefore, the read data write-back to a ferroelectric memory cell is locally controlled and begins quickly after reading data from the ferroelectric memory cell, thereby allowing a quick cycle time.

Abstract: A memory circuit includes a bit cell that receives a word line, complementary bit lines and an array supply voltage; a word line driver coupled to the word line, the word line driver receiving one of the array supply voltage and a periphery supply voltage; and a word line suppression circuit coupled to the word line. The word line suppression circuit includes a diode and a switch coupled in series. The switch is responsive to the array supply voltage. The word line suppression circuit limits a word line voltage to a value lower than the array supply voltage such that the static noise margin (SNM) of the bit cell is increased.

Abstract: A memory array has a memory cell that comprises a storage element storing a logical state at a reduced voltage during at least one functional operation and a write access circuit configured to connect the storage element to at least a first write bit line in response to a write signal on the write word line for writing the logical state to the memory cell. The memory cell further comprises a read access circuit including an input node connected to the storage element and an output node connected to a read bit line of the memory array. The read access circuit is enabled and configured to read the logic state of the storage element in response to a read signal on the read word line. The reduced voltage is reduced relative to an operating voltage of at least one peripheral circuit associated with reading and/or writing of the memory cell.

Abstract: Bias circuitry for a static random-access memory (SRAM) with a retain-till-accessed (RTA) mode and with write assist bias in a normal operating mode. The memory is constructed of multiple memory array blocks of SRAM cells. Bias devices are associated with each memory array block, and associated with one or more columns. Each bias device includes a diode-connected transistor in parallel with a shorting transistor, between a power supply voltage and a power supply bias node for cells in its column or columns. The shorting transistor receives control signals from control logic so that the diode-connected transistor for each column is shorted during read cycles, and in write cycles in which its columns are not selected; in write cycles in which its columns are selected, the shorting transistor in the bias device is turned off, so that a reduced power supply voltage is applied to the selected column. The shorting transistors for all columns in the block are turned off in the RTA mode.

Abstract: A memory array has a memory cell that comprises a storage element storing a logical state at a reduced voltage during at least one functional operation and a write access circuit configured to connect the storage element to at least a first write bit line in response to a write signal on the write word line for writing the logical state to the memory cell. The memory cell further comprises a read access circuit including an input node connected to the storage element and an output node connected to a read bit line of the memory array. The read access circuit is enabled and configured to read the logic state of the storage element in response to a read signal on the read word line. The reduced voltage is reduced relative to an operating voltage of at least one peripheral circuit associated with reading and/or writing of the memory cell.

Abstract: A memory array is provided having a memory cell coupled to a read word line and a write word line of the memory array and peripheral circuits for reading and writing to the memory cell. The memory cell comprises a storage element for storing a logical state of the memory cell powered at a reduced voltage during at least one functional operation and a write access circuit configured to connect the storage element to at least a first write bit line in the memory array in response to a write signal on the write word line for writing the logical state to the memory cell. The memory cell further comprises a read access circuit including an input node connected to the storage element and an output node connected to a read bit line of the memory array. The read access circuit is enabled and configured to read the logic state of the storage element in response to a read signal on the read word line.

Abstract: A ferroelectric apparatus includes a circuit having a first capacitor electrically coupled to a plate line via a top terminal connection of the first ferroelectric capacitor and to a storage node via a bottom terminal connection of the first ferroelectric capacitor. The circuit also includes a second ferroelectric capacitor electrically coupled to a second plate line via a second bottom terminal connection of the second ferroelectric capacitor and to the storage node via a second top terminal connection of the second ferroelectric capacitor.

Abstract: A self-timed sense amplifier read buffer pulls down a pre-charged high global bit line, which then feeds data into a tri state write back buffer that is connected directly to the bit line. The bit line provides charge to a ferroelectric capacitor to write a logical “one” or “zero” while by-passing an isolator switch disposed between the sense amplifier and the ferroelectric capacitor. Because the sense amplifier uses grounded bit line sensing, the read buffer will not start pulling down the global bit line until after the sense amplifier signal amplification, which makes the timing of the control signal for this read buffer non-critical. The write-back buffer enable timing is also self-timed off of the sense amplifier. Therefore, the read data write-back to a ferroelectric memory cell is locally controlled and begins quickly after reading data from the ferroelectric memory cell, thereby allowing a quick cycle time.

Abstract: An FRAM device can comprise a sense amplifier, at least a first bitcell, a first control line, and a second control line. The first bitcell can have a bit line that connects to the sense amplifier via a first isolator and a complimentary bit line that connects to the sense amplifier via a second isolator that is different from the first isolator. The first control line can connect to and control the aforementioned first isolator. And the second control line can connect to and control the second isolator such that the second isolator is independently controlled with respect to the first isolator to facilitate testing the device.

Abstract: A ferroelectric memory device includes a shunt switch configured to short both sides of the ferroelectric capacitor of the ferroelectric memory device. The shunt switch is configured therefore to remove excess charge from around the ferroelectric capacitor prior to or after reading data from the ferroelectric capacitor. By one approach, the shunt switch is connected to operate in reaction to signals from the same line that controls accessing the ferroelectric capacitor. So configured, the high performance cycle time of the ferroelectric memory device is reduced by eliminating delays used to otherwise drain excess charge from around the ferroelectric capacitor, for example by applying a precharge voltage. The shunt switch also improves reliability of the ferroelectric memory device by ensuring that excess charge does not affect the reading of the ferroelectric capacitor during a read cycle.