Abstract: An integrated semiconductor memory chip includes hardwired presence detect data which can be accessed for transmission to a location external to the memory chip as well as logic allowing additional presence detect data to be programmed in the memory chip after fabrication of the memory chip. Storing the presence detect data on the memory chip rather than on a separate integrated circuit can help reduce the number of integrated chips required for a memory module, which may include multiple DRAM or other memory chips. Hardwiring at least some of the presence detect data during fabrication of the chip can reduce the number of programming errors as well as the number of mismatches that might otherwise occur if a separate presence detect data chip were used. On the other hand, the capability of programming presence detect data after fabrication of the memory chip provides additional flexibility, allowing the foregoing techniques to be used with a wide variety of memory chips and modules.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: A circuit and method for actively driving a reference voltage in a memory device is disclosed. A circuit integrated in a memory device and coupled to an external voltage source substantially eliminates fluctuations in the reference voltage of the memory device caused by power supply changes and noise occurring in the memory device by generating a constant voltage and good current drive from the external voltage source.

Abstract: An integrated circuit includes an embedded memory device and an on-chip test circuit. The on-chip test circuit includes a multiplexer and one or more I/O circuits. The multiplexer allows the I/O circuits to interface with a plurality of inputs and outputs associated with the embedded memory device. As a result, the embedded memory device in the integrated circuit may be tested or repaired after the embedded memory array portion of the integrated circuit is formed, yet prior to fabrication of dedicated input/output circuitry. This allows evaluation of the embedded memory device in the integrated circuit prior to committing resources to complete fabrication of the entire integrated circuit.

Abstract: A synchronous double-data-rate semiconductor memory device is adapted to receive write data on both the rising and falling edges of a data strobe signal derived from an externally-applied system clock. In the write path circuitry for each data pin of the device, adjustable delay elements are provided to enable the adjustment of the setup and hold times of write data applied to the data pin relative to the data strobe signal. The delays are separately adjustable for data present during the rising edge of the data strobe signal and for data present during the falling edge of the data strobe signal. The setup and hold window for write data is thus optimizable on a per-bit basis rather than a per-cycle basis. In one embodiment, a delay circuit is provided for generating delaying the rising edge data and the falling edge data by different delay intervals.

Abstract: An embodiment of the present invention discloses a memory device having an array with digit lines arranged in complementary pairs, the array comprising; a substantially planar layer having trenches therein; a first level of digit lines residing at least partially in the trenches; a second level of digit lines residing on the surface of the layer, the second level extending in generally parallel relation to the digit lines in the first level. The first level of digit lines are in alternating positions with the second level of digit lines and the alternating positions comprise a repeating pattern of a first complementary pair of digit lines at the first level adjacent a second complementary pair of digit lines at the second level.

Abstract: A method and apparatus for storing and retrieving data in a second, or higher, order prefetch architecture memory integrated circuit. The method includes storing multiple bits of data in memory cells at various electrical distances from an output buffer and retrieving those memory bits concurrently for output. By outputting the bits in a fixed burst order, according to which a bit from a memory cell closer to the output buffer is output before a bit from a memory cell farther from the output buffer, the output time of the data bit from the closer memory cell can be used to mask a portion of the transit time of the bit from the farther memory cell. The apparatus includes memory cells at various locations for storing data bits, an address decoder adapted to store and retrieve multiple bits in a fixed burst order, and a multiplexer.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: A circuit and method for actively driving a reference voltage in a memory device is disclosed. A circuit integrated in a memory device and coupled to an external voltage source substantially eliminates fluctuations in the reference voltage of the memory device caused by power supply changes and noise occurring in the memory device by generating a constant voltage and good current drive from the external voltage source.

Abstract: A method and apparatus for compensating a delay locked loop against signal timing variances after circuit initialization which cause delay shifts due to temperature and voltage changes and operational noise. A delay line of a delay locked loop is disclosed, the delay line having a plurality of delay elements and a minimum and maximum delay boundary. According to an embodiment of the invention, an artificial minimum or maximum boundary, or both, is established on the delay line such that during initialization of the delay locked loop circuit, the circuit cannot lock on a delay element beyond the artificial minimum or maximum boundaries. By offsetting the artificial minimum and maximum boundaries from the actual minimum and maximum boundaries of the delay line, a buffer of delay elements is established at the actual delay line boundaries.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: A delay locked loop having improved synchronization times has a variably adjustable delay line which accepts two incoming clock pulses. As each pulse propagates through the delay line an edge of the pulse toggles or retoggles a shift bit corresponding to a delay element. When the first pulse reaches the end of the delay line, the status of the shift bits is frozen, and a starting point for a synchronization sequence begins at the transition point between toggled and retoggled shift bits.

Abstract: A delay locked loop having improved synchronization times has a variably adjustable delay line which accepts two incoming clock pulses. As each pulse propagates through the delay line an edge of the pulse toggles or retoggles a shift bit corresponding to a delay element. When the first pulse reaches the end of the delay line, the status of the shift bits is frozen, and a starting point for a synchronization sequence begins at the transition point between toggled and retoggled shift bits.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: An integrated circuit includes an embedded memory device and an on-chip test circuit. The on-chip test circuit includes a multiplexer and one or more I/O circuits. The multiplexer allows the I/O circuits to interface with a plurality of inputs and outputs associated with the embedded memory device. As a result, the embedded memory device in the integrated circuit may be tested or repaired after the embedded memory array portion of the integrated circuit is formed, yet prior to fabrication of dedicated input/output circuitry. This allows evaluation of the embedded memory device in the integrated circuit prior to committing resources to complete fabrication of the entire integrated circuit.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.

Abstract: As part of a memory array, a circuit is provided for altering the drive applied to an access transistor that regulates electrical communication within the memory array. In one embodiment, the circuit is used to alter the drive applied to a sense amp's voltage-pulling transistor, thereby allowing modification of the voltage-pulling rate for components of the sense amp. A sample of test data is written to the memory array and read several times at varying drive rates in order to determine the sense amp's ability to accommodate external circuitry. In another embodiment, the circuit is used to alter the drive applied to a bleeder device that regulates communication between the digit lines of the memory array and its cell plate. Slowing said communication allows defects within the memory array to have a more pronounced effect and hence increases the chances of finding such defects during testing.