Abstract: A flash memory device programs cells in each row in a manner that minimizes the number of programming pulses that must be applied to the cells during programming. The flash memory device includes a pseudo pass circuit that determines the number of data errors in each of a plurality of subsets of data that has been programmed in the row. The size of each subset corresponds to the number of read data bits coupled from the memory device, which are simultaneously applied to error checking and correcting circuitry. During iterative programming of a row of cells, the pseudo pass circuit indicates a pseudo pass condition to terminate further programming of the row if none of the subsets of data have a number of data errors that exceeds the number of data errors that can be corrected by the error checking and correcting circuitry.

Abstract: A flash memory device programs cells in each row in a manner that minimizes the number of programming pulses that must be applied to the cells during programming. The flash memory device includes a pseudo pass circuit that determines the number of data errors in each of a plurality of subsets of data that has been programmed in the row. The size of each subset corresponds to the number of read data bits coupled from the memory device, which are simultaneously applied to error checking and correcting circuitry. During iterative programming of a row of cells, the pseudo pass circuit indicates a pseudo pass condition to terminate further programming of the row if none of the subsets of data have a number of data errors that exceeds the number of data errors that can be corrected by the error checking and correcting circuitry.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: A method of managing power consumption by a memory in a memory device includes determining whether the device is powered by a depletable power supply, and if it is determined that the device is powered by a depletable power supply, changing a behavior of the memory to regulate power consumed by the memory.

Abstract: An integrated circuit operable in a test mode and a normal operating mode, which includes an improved test mode switch. In the test mode of preferred embodiments in which the circuit is an integrated memory chip, the test mode switch is closed so as to connect an input/output (I/O) pad directly with a selected memory cell (so a current/voltage characterization of the cell can be obtained). In the normal operating mode of these embodiments, the test mode switch is open and it isolates the I/O pad from direct connection with the selected cell even under the condition that a transistor of the test mode switch undesirably becomes conductive (e.g., due to low voltage on the I/O pad, inductive coupling, or the like).

Abstract: A memory system operable in a normal mode of operation and a test mode of operation includes sensing circuitry which generates x number of data bits during a read cycle. A read path circuit, coupled to the sensing circuitry, transfers the x number of data bits generated by the sensing circuitry during a first read cycle in the normal mode of operation to x number of output nodes. A first detection circuit, coupled to the read path circuit, detects whether or not the x number of data bits generated by the sensing circuitry during a second read cycle in the test mode of operation are arranged in a pattern in which all bits are identical. A second detection circuit, coupled to the read path circuit, detects whether or not the x number of data bits generated by the sensing circuitry during the second read cycle in the test mode of operation are arranged in a pattern in which each two adjacent bits are different.

Abstract: An integrated circuit selectively operable in either a first mode (consuming low power) or a second mode (consuming relatively high power). The circuit includes MOS transistors and a supply voltage circuit for at least one of the transistors. In both modes, the supply voltage circuit holds the body of each transistor at a fixed voltage (e.g., a voltage V.sub.CC in a range from 5 to 5.5 volts, where each transistor is a PMOS device). In the second mode the supply voltage circuit supplies this fixed voltage to the source of each transistor, but in the first mode it supplies a voltage equal to or slightly offset from the fixed voltage to the source of each transistor. In some embodiments, the supply voltage circuit (in the first mode, after an initial transient state) supplies a first voltage to a well shared by a plurality of PMOS transistors, and a second voltage to the source of each PMOS device.

Abstract: An integrated circuit operable in a test mode and a normal operating mode, which includes an improved test mode switch. In the test mode of preferred embodiments in which the circuit is an integrated memory chip, the test mode switch is closed so as to connect an input/output (I/O) pad directly with a selected memory cell (so a current/voltage characterization of the cell can be obtained). In the normal operating mode of these embodiments, the test mode switch is open and it isolates the I/O pad from direct connection with the selected cell even under the condition that a transistor of the test mode switch undesirably becomes conductive (e.g., due to low voltage on the I/O pad, inductive coupling, or the like).

Abstract: An integrated circuit selectively operable in either a first mode (consuming low power) or a second mode (consuming relatively high power). The circuit includes MOS transistors and a supply voltage circuit for at least one of the transistors. In both modes, the supply voltage circuit holds the body of each transistor at a fixed voltage (e.g., a voltage V.sub.cc in a range from 5 to 5.5 volts, where each transistor is a PMOS device). In the second mode the supply voltage circuit supplies this fixed voltage to the source of each transistor, but in the first mode it supplies a voltage equal to or slightly offset from the fixed voltage to the source of each transistor. In some embodiments, the supply voltage circuit (in the first mode, after an initial transient state) supplies a first voltage to a well shared by a plurality of PMOS transistors, and a second voltage to the source of each PMOS device.

Abstract: A memory system operable in a normal mode of operation and a test mode of operation includes sensing circuitry which generates x number of data bits during a read cycle. A read path circuit, coupled to the sensing circuitry, transfers the x number of data bits generated by the sensing circuitry during a first read cycle in the normal mode of operation to x number of output nodes. A first detection circuit, coupled to the read path circuit, detects whether or not the x number of data bits generated by the sensing circuitry during a second read cycle in the test mode of operation are arranged in a pattern in which all bits are identical. A second detection circuit, coupled to the read path circuit, detects whether or not the x number of data bits generated by the sensing circuitry during the second read cycle in the test mode of operation are arranged in a pattern in which each two adjacent bits are different.

Abstract: An integrated circuit operable in a test mode and a normal operating mode, which includes an improved test mode switch. In the test mode of preferred embodiments in which the circuit is an integrated memory chip, the test mode switch is closed so as to connect an input/output (I/O) pad directly with a selected memory cell (so a current/voltage characterization of the cell can be obtained). In the normal operating mode of these embodiments, the test mode switch is open and it isolates the I/O pad from direct connection with the selected cell even under the condition that a transistor of the test mode switch undesirably becomes conductive (e.g., due to low voltage on the I/O pad, inductive coupling, or the like).

Abstract: A circuit which responds to an external standby command (a transition in a chip enable signal from an external device) by generating a delayed internal standby signal. The internal standby signal functions by switching selected components of the circuit (such as address buffers) from an active mode to a standby mode. In preferred embodiments, the circuit is a memory circuit implemented as an integrated circuit. The amount of the delay in generating the delayed internal standby signal is selected to achieve a desired decreased average response time to a sequence of commands (such as memory access commands) without excessive power consumption. In embodiments in which the circuit is a memory chip (such as a flash memory chip) having address access time in the range from 60 ns to 80 ns, the delay typically is from about 100 ns to about 200 ns.

Abstract: A method for verifying the status of selected nonvolatile memory cells of an integrated memory circuit, such as during a memory erase or programming operation, and an integrated nonvolatile memory circuit including circuitry for performing this verification method. Preferably, the invention employs simple logic circuitry including a flip-flop to assert successful verification data only in response to a continuous validity of a verification signal throughout a sampling period, thereby avoiding false assertion of successful verification data. The sampling period is preferably longer than the expected duration of fluctuations due to noise in the verification signal. During the sampling period of a verification operation, the logic circuitry receives a raw verification signal indicative of the instantaneous relation between a measured threshold voltage of a selected memory cell and a reference voltage.